An electronic breadboard system may include a computing device including a display screen. The display screen has a first portion to display an electronic circuit model and a second portion directly adjacent to the first portion. The electronic breadboard system also includes a translucent breadboard on the second portion of the display screen. The translucent breadboard includes a translucent face plate having a rectangular grid of openings exposing a plurality of contacts. The plurality of contacts are arranged lengthwise along each row of the rectangular grid of openings and orthogonal to a transparent back plate coupling the plurality of contacts to the translucent face plate. The electronic breadboard system includes a graphics controller. The graphics controller may illuminate a row opening and/or a column opening of the translucent breadboard to direct placement of electrical components of a computer model in response to user interaction with the electronic circuit model.

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.

The invention concerns a function component upper part (500) for placing on a function component lower part (401) of a function component (400), having a first interface for electrically connecting the function component lower part (401) of the function component (400), and a second interface for electrically 409 connecting a housing upper part (403) of the function component (400).

A separated back plane design within a server rack is provided which allows for the hot-swapping of a control module board. The separated back plane design consists of a base plane board and a control module board which connects to the base plane board. The base plane board can draw power from a power supply and can connect a number of electrical components which are not significantly susceptible to damage or failure. The control module board can consist of a number of other electrical components, which are susceptible to damage or failure. The control module board connects to the base plane board, and can be removed during failure of the control module board. When the control module board is removed from the base plane board, the base plane board and its functions continue to operate, and power need not be shut off in order to replace the control module board.

An electronic breadboard system may include a computing device including a display screen. The display screen has a first portion to display an electronic circuit model and a second portion directly adjacent to the first portion. The electronic breadboard system also includes a translucent breadboard on the second portion of the display screen. The translucent breadboard includes a translucent face plate having a rectangular grid of openings exposing a plurality of contacts. The plurality of contacts are arranged lengthwise along each row of the rectangular grid of openings and orthogonal to a transparent back plate coupling the plurality of contacts to the translucent face plate. The electronic breadboard system includes a graphics controller. The graphics controller may illuminate a row opening and/or a column opening of the translucent breadboard to direct placement of electrical components of a computer model in response to user interaction with the electronic circuit model.

A split backplane for a telecommunication, networking, or computing device includes a power backplane comprising power connectors; a signal backplane comprising signal connectors, wherein the signal backplane is separate from the power backplane, and wherein one or more modules are adapted to selectively connect to the power connectors and the signal connectors simultaneously; and an alignment bar connected between the power backplane and the signal backplane for alignment and stiffening of the power backplane and the signal backplane together for signal integrity and to prevent connector pins from bending or failing between the one or more modules, the power connectors, and the signal connectors.

A split backplane for a telecommunication, networking, or computing device includes a power backplane comprising power connectors; a signal backplane comprising signal connectors, wherein the signal backplane is separate from the power backplane, and wherein one or more modules are adapted to selectively connect to the power connectors and the signal connectors simultaneously; and an alignment bar connected between the power backplane and the signal backplane for alignment and stiffening of the power backplane and the signal backplane together for signal integrity and to prevent connector pins from bending or failing between the one or more modules, the power connectors, and the signal connectors.

A circuit board assembly, a backplane interconnection system, and an electronic device are disclosed. The circuit board assembly includes a bracket and a circuit board, the circuit board is formed with a fastened part and a free part, the fastened part is connected to the bracket, the free part is suspended, a surface on which the free part and the fastened part are co-located is a first plane, the free part has an amplitude of swing in a first direction, the first direction is perpendicular to the first plane, the circuit board is configured to plug-connect to a front sub-circuit board, a first connector plug-connected to a first plug-connection end on the front sub-circuit board is disposed on the free part, and the amplitude of swing is capable of enabling the first connector to plug-connect to the first plug-connection end.

A storage-device bay includes a fixed-side bracket and a movable connector subassembly that translates along an insertion axis. The subassembly carries a connector PCBA with a mating connector and is biased toward the fixed-side bracket by at least one resilient member, preferably springs captured under abutments such as screw heads on the bracket. During insertion, the device-side connector mates while the subassembly translates against the bias; in a seated state, the bias maintains axial compressive preload across the mated connectors to absorb tolerances and improve contact reliability. Variants include a travel stop, alignment features, a PCBA support plate, multi-connector PCBA for multi-bay use with group translation, and independently movable sections providing localized preload per bay.