An inverter apparatus includes a main circuit substrate, an EMC filter substrate, a control substrate, and a panel. The main circuit substrate is configured to convert electric power and includes an output terminal through which the electric power is output from the inverter apparatus. The EMC filter substrate is provided on the main circuit substrate and configured to reduce propagation of electromagnetic noise. The EMC filter substrate includes a first input terminal through which the electric power is input to the inverter apparatus. The control substrate is provided on the EMC filter substrate so that the EMC filter substrate is sandwiched between the main circuit substrate and the control substrate. The control substrate is configured to control the main circuit substrate. The panel is provided on the control substrate so that the control substrate is sandwiched between the EMC filter substrate and the panel.

An inverter apparatus includes a main circuit substrate, an EMC filter substrate, a control substrate, and a panel. The main circuit substrate is configured to convert electric power and includes an output terminal through which the electric power is output from the inverter apparatus. The EMC filter substrate is provided on the main circuit substrate and configured to reduce propagation of electromagnetic noise. The EMC filter substrate includes a first input terminal through which the electric power is input to the inverter apparatus. The control substrate is provided on the EMC filter substrate so that the EMC filter substrate is sandwiched between the main circuit substrate and the control substrate. The control substrate is configured to control the main circuit substrate. The panel is provided on the control substrate so that the control substrate is sandwiched between the EMC filter substrate and the panel.

Embodiments of the disclosure provide a cable connection structure, including: a bearing member, the bearing member being provided with at least one cable connector, and each cable connector having a first port connected to a cable and a second port electrically connected to the first port; and a sliding structure connected to the bearing member, the bearing member being configured to be connected to a single board through the sliding structure, the bearing member enabling the single board connected to the bearing member to slide in a first direction which is a direction close to or away from the second port. Embodiments of the disclosure also provide a single-board assembly and a single-board assembly connection structure.

Embodiments of the disclosure provide a cable connection structure, including: a bearing member, the bearing member being provided with at least one cable connector, and each cable connector having a first port connected to a cable and a second port electrically connected to the first port; and a sliding structure connected to the bearing member, the bearing member being configured to be connected to a single board through the sliding structure, the bearing member enabling the single board connected to the bearing member to slide in a first direction which is a direction close to or away from the second port. Embodiments of the disclosure also provide a single-board assembly and a single-board assembly connection structure.

A cable shield tunnel for an electrical device includes a ground bus and a floor shim, discrete from the ground bus, and coupled to a circuit card and forming a cable tunnel that receives an end of a cable. The ground bus includes an end wall extending along a first end of the cable tunnel, a first side wall extending from the end wall along a first side of the cable tunnel, and a second side wall extending from the end wall along a second side of the cable tunnel opposite the first side. The first and second side walls are configured to be coupled to the circuit card. The floor shim is provided at a second end of the cable tunnel opposite the first end and is positioned between the cable and the circuit card.

A cable shield tunnel for an electrical device includes a ground bus and a floor shim, discrete from the ground bus, and coupled to a circuit card and forming a cable tunnel that receives an end of a cable. The ground bus includes an end wall extending along a first end of the cable tunnel, a first side wall extending from the end wall along a first side of the cable tunnel, and a second side wall extending from the end wall along a second side of the cable tunnel opposite the first side. The first and second side walls are configured to be coupled to the circuit card. The floor shim is provided at a second end of the cable tunnel opposite the first end and is positioned between the cable and the circuit card.

A miniaturized paddle card assembly that provides high-speed, high-performance transmission. The paddle card has two or more rows of contact pads for mating with complementary conductors, two or more rows of terminals for cable termination, and alternating dielectric layers and metal layers. The two or more rows of terminals are disposed on respective metal layers. Such a configuration enables conductive traces electrically connecting corresponding contact pads and terminals to be substantially straight, and therefore reduces the lengths of the conductive traces. It is also reduced that the size of the paddle card in both a lateral direction parallel to the rows and a longitudinal direction perpendicular to the lateral direction, without changing the thickness of the paddle card. With the paddle card assembly provided herein, the integrity of the signals transmitted therethrough can be maintained and/or improved at higher speed.

An electrical connector includes: an insulative housing having a top wall and a pair of side walls; and a substrate secured to the insulative housing to constitute a bottom wall of the insulative housing, the substrate having plural front conductive pads at an upper face thereof and plural rear conductive pads at a lower face thereof in electrical connection with the plural front conductive pads.

A terminal connected to the end of an electrical wire, including: a main body portion connected to a core wire of the electrical wire and a contacting portion connected to the front end of the main body portion having a portion with a U-shaped cross-section that connects to a mating terminal, wherein the contacting portion includes: an upper plate portion connected to the main body portion, a lower plate portion that is parallel with the upper plate portion, a side plate portion that connects one of either the left or right edges of the upper plate portion and the lower plate portion, a tip mating recessed portion demarcated on three sides by the upper plate portion, the lower plate portion, and the side plate portion, an inclined protruding piece that extends diagonally downward from the back end of the lower plate portion, and a middle plate portion that extends between the inclined protruding piece and the upper plate portion in the width direction of the contacting portion.

A terminal connected to the end of an electrical wire, including: a main body portion connected to a core wire of the electrical wire and a contacting portion connected to the front end of the main body portion having a portion with a U-shaped cross-section that connects to a mating terminal, wherein the contacting portion includes: an upper plate portion connected to the main body portion, a lower plate portion that is parallel with the upper plate portion, a side plate portion that connects one of either the left or right edges of the upper plate portion and the lower plate portion, a tip mating recessed portion demarcated on three sides by the upper plate portion, the lower plate portion, and the side plate portion, an inclined protruding piece that extends diagonally downward from the back end of the lower plate portion, and a middle plate portion that extends between the inclined protruding piece and the upper plate portion in the width direction of the contacting portion.