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.

Methods and apparatus for an assembly including a circuit card coupled to an alignment bracket having a bracket mounting hole with an interposer board having a front and back connectors and a mounting hole. The front connector is mated with the circuit card and the back connector is configured and positioned to mate with a test connector of a unit under test (UUT). An alignment plate has a plate mounting hole. First and second alignment pins may be rotatably engaged to position the connectors in relation to the alignment plate.

A controller and a rectangular parallelepiped power supply apparatus are coupled to a rear surface of a midplane, to which a plurality of storage media drives are coupled in a front surface of the midplane. A plurality of interface connectors arranged in a left-right direction are provided at a front end of a controller substrate. The rear surface of the midplane includes a plurality of connectors for controller, which are a plurality of connectors arranged in the left-right direction to which interface connectors of the controller are respectively coupled, and a connector for power supply, which are connectors to which a power supply apparatus set horizontally is coupled. A part of a row of the connectors for controller is present below the power supply apparatus coupled sideways to the connector for power supply.

A scalable system for high-power computer, comprising a plurality of motherboard chassis, inserted in a computer rack mounting kit, each motherboard chassis, being configured to receive at least one motherboard module, said plurality of inner chassis forming a stack of inner chassis, the stack being configured to receive an outer floating bracket chassis, said outer chassis being inserted by a second longitudinal end of each inner chassis forming the stack of inner chassis, each said outer floating bracket chassis being configured to accommodate at least one double floating bracket being configured to house a cable box capable of connecting the connectors of a plurality of motherboard modules, arranged in said inner chassis of the stack, to each other, the system being characterized in that the double floating bracket comprises at least several floating attachment means.

Provided is a miniaturized computation and storage merged system, which relates to the fields of communications, information, industrial control and the like. The miniaturized computation and storage merged system includes: a mid-back board having a plurality of board card slots; a first processing board which is connected with the mid-back board; a second processing board which is connected with the mid-back board; and one or more rear-inserted board cards, each of which is fixed on the mid-back board via a board card slot, wherein the one or more rear-inserted board cards are configured to provide support in data storage and/or computation for the first processing board and the second processing board, to enable the first processing board and the second processing board to complete a data storage and/or computation task. The system has a very high expansibility and a very high popularity.

A system compatible for use with ATCA includes a chassis comprising a first and a second plurality of slots for receiving circuit boards. The chassis further includes a midplane having a front surface and a back surface. The midplane extends between the first plurality of slots and the second plurality of slots. The midplane has a first plurality of connectors affixed to the front surface and has a second plurality of connectors affixed to the back surface. Each connector is arranged to accept a circuit board. The midplane forms an interconnection scheme such that one of the first plurality of slots is directly connected to one of the second plurality of slots. The one of the first plurality of slots and the one of the second plurality of slots extend in opposite directions from their respective connections on the midplane.

A midplane communication system includes: a midplane; at least one front daughter card configured to connect to a front side of the midplane; at least one rear daughter card configured to connect to a rear side of the midplane in a vertical direction relative to the front daughter card; and an orthogonal connector configured to electrically connect the front daughter card and the rear daughter card, wherein the orthogonal connector is configured to connect to the midplane at a vertical or horizontal offset to include at least one extra connection pin allowing an additional connection when connecting the front daughter card and the rear daughter card.

A computer chassis for accepting a front module and a rear module without a midplane board is disclosed. A middle bracket positioned within the chassis facilitates alignment of connectors of the front module and rear module, which can be directly connected together by applying sufficient force. The rear module can be inserted into the chassis and can automatically lock in place, thereby allowing force applied from the front module to be used to connect the connectors of the front module and rear module together, rather than pressing the rear module out of the chassis. The rear module can further include elements to improve safety and structure. In some cases, supplemental locking mechanisms can be used to ensure the rear module cannot be removed until certain sub-modules (e.g., a power supply unit) has been removed.

A wiring substrate is connected to a backplane, and includes: a first connector that is mounted on one surface of the wiring substrate and is connected to the backplane; an opening portion that is formed in the one surface on a side opposite to a side connected to the backplane of the first connector, and through which a cable having one end connected to the first connector is passed; an integrated circuit that is mounted on the one surface on a side opposite to a side on which the first connector is present relative to the opening portion; and a second connector that is mounted on the other surface on a side opposite to the one surface in the vicinity of the integrated circuit on the side opposite to the side on which the first connector is present relative to the opening portion, is connected to the integrated circuit via a through hole penetrating the wiring substrate, and is connected to the other end of the cable.

A controller and a rectangular parallelepiped power supply apparatus are coupled to a rear surface of a midplane, to which a plurality of storage media drives are coupled in a front surface of the midplane. A plurality of interface connectors arranged in a left-right direction are provided at a front end of a controller substrate. The rear surface of the midplane includes a plurality of connectors for controller, which are a plurality of connectors arranged in the left-right direction to which interface connectors of the controller are respectively coupled, and a connector for power supply, which are connectors to which a power supply apparatus set horizontally is coupled. A part of a row of the connectors for controller is present below the power supply apparatus coupled sideways to the connector for power supply.