A structure is provided for a structure for providing electrical connections across a connection interface is provided. The structure may include one or more signal connections, a plurality of reference connections, and one or more high-pass filters. One or more of the reference connections is configured to connect a first reference voltage in a first region on a first side of the interface with a second reference voltage in a second region on a second side of the interface. One or more of the reference connections in a first class of reference connections is coupled one or more of the reference voltages through the one or more high-pass filters, and low-bandwidth information is communicated across the one or more reference connections in the first class of reference connection.

An electronic device configured to be mounted in a housing of a cluster, the device comprising a rear body housing at least one mother board configured to be powered by the cluster, a front tray housing at least one electronic board having at least one socket, the front tray comprising at least one fastening member for mounting an expansion card having an edge connector and a fastening portion, the electronic board being connected to the mother board by at least one flexible cable, the front tray being mounted slidable relatively from the rear body between a close position and an open position in which the front tray is at least partially removed from the cluster housing while keeping the rear body into the cluster housing so that an expansion card can be mounted/unmounted from the electronic board without powering off the device.

A mother board with a central processing unit and two riser slots configured to cooperate with one riser card for connecting two expansion cards to the mother board. The first riser slot and the second riser slot may be connected by metal traces to the central processing unit, and the two riser slots may be spaced apart by a distance greater than 8 cm.

A busbar assembly includes a base having a width and a length. The base has a first surface and a second surface and has a first side and a second side. A distance between the first side and the second side comprises the width, and the base defines a slot centered between approximately 75% and approximately 79% of the width.

The present disclosure provides a fixing device for fixing an external electronic component on a motherboard in a chassis. The fixing device includes a fixing block and a telescopic block. The fixing block is fixed on the chassis. One end of the telescopic block is slidably mounted in the fixing block, the other end protrudes from the fixing block and holds the electronic component. A chassis including the above-described fixing device to hold electronic components of different sizes is also provided.

A structure is provided for a structure for providing electrical connections across a connection interface is provided. The structure may include one or more signal connections, a plurality of reference connections, and one or more high-pass filters. One or more of the reference connections is configured to connect a first reference voltage in a first region on a first side of the interface with a second reference voltage in a second region on a second side of the interface. One or more of the reference connections in a first class of reference connections is coupled one or more of the reference voltages through the one or more high-pass filters, and low-bandwidth information is communicated across the one or more reference connections in the first class of reference connection.

A fixing device for fixing a display card on a circuit board, includes a backplane and a support bracket. The backplane includes a substrate plate, and a first engaging part. The substrate plate is fixed on the display card. The first engaging part is disposed on the substrate plate. The support bracket includes at least one support leg and a second engaging part. The support leg includes a first end and a second end. The first end is connected with the circuit board. The second engaging part is connected with the second end and engaged with the first engaging part.

A flexible input/output (I/O) expansion card connection and communication technique are provided. The flexible I/O expansion card is, in some examples, a mezzanine expansion card that may be a single width mezzanine expansion card, a double width expansion card, or a quad width expansion card. Multiple connectors on a mainboard provide a slot to receive plug in (insertion) of an expansion card. A slot is associated with a communication bus (e.g., Peripheral Component Interconnect (PCI)) established between the expansion card and an associated processor. The expansion card (or more than one expansion card) may be inserted in multiple orientations with respect to the multiple connectors. Automatic adjustment of communication on the communication bus may be implemented via one or more hardware level and/or software assisted translations to allow the mezzanine expansion card to function in a normal or a reverse (180 degrees relative to normal) orientation.

A busbar assembly includes a base having a width and a length. The base has a first surface and a second surface and has a first side and a second side. A distance between the first side and the second side comprises the width, and the base defines a slot centered between approximately 75% and approximately 79% of the width.

A busbar assembly includes a base having a width and a length. The base has a first surface and a second surface and has a first side and a second side. A distance between the first side and the second side comprises the width, and the base defines a slot centered between approximately 75% and approximately 79% of the width.