A modular I/O device includes a terminal base with a terminal block that includes a plurality of wiring connectors. An auxiliary wiring device includes a plurality of auxiliary wiring connectors and is selectively physically connectable to the terminal base in an operative position and selectively physically removable from the terminal base. The terminal block includes a receiver and the auxiliary wiring device includes a body including at least one mounting tab that projects outwardly from the body and that is located in the receiver. The receiver includes a projecting lip about which the auxiliary wiring device is pivotable relative to the receiver on a pivot axis. The terminal base includes at least one catch and the auxiliary wiring device further includes at least one latch arm that is adapted to engage the catch when the auxiliary wiring device is physically connected to said terminal base in its operative position.

A bussing connector is provided and includes bus bar connections, output elements and dielectric material. The bus bar connections each include an output section and an input section. The input sections cooperatively form a multiphase alternating current (AC) input. The output elements are arranged along and in electrical communication with the output sections of each of the bus bar connections. The dielectric material is configured to partially surround and partially electrically insulate the input and output sections and the output elements of each of the bus bar connections. The dielectric material is further configured to expose the multiphase AC input and portions of each of the outlet elements of each of the bus bar connections.

A high-frequency module includes a module substrate having major surfaces, and a module substrate having major surfaces. The major surface are disposed facing the major surface. A first electronic component includes a filter coupled to a power amplifier and a low-noise amplifier. A second electronic component includes a filter coupled to a low-noise amplifier. A third electronic component includes a switch coupled between filters and an antenna connection terminal. The first electronic component is disposed between the major surfaces, on the major surface, or on the major surface. The second electronic component is disposed between the major surfaces, on the major surface, or on the major surface where the first electronic component is not disposed. The third electronic component is disposed between the major surfaces, on the major surface, or on the major surface wherein neither of the first nor second electronic component is disposed.

A housing includes a frame having a frame peripheral wall which forms a lower opening, the frame peripheral wall having a frame side seam, and a lower cover having a cover side seam which is engaged with the frame side seam, and configured to cover the lower opening. The lower cover has a first shield wall protruding outward from the cover side seam, and a second shield wall protruding from the first shield wall toward an upper side of the frame. The second shield wall is located outward than a mating surface between the frame side seam and the cover side seam, and a wall inner surface of the second shield wall faces an outer surface of the frame peripheral wall.

An apparatus for providing forced flow cooling in a circuit card environment is provided includes at least one circuit card including first and second longitudinally spaced circuit card subassemblies, connected together into a single circuit card oriented substantially in a lateral-longitudinal plane. The first and second circuit card subassemblies have first and second operating temperatures, which are different from one another. A housing defines a housing internal volume which completely three-dimensionally surrounds the circuit card. A first temperature-control fluid is directed laterally across at least a portion of the first circuit card subassembly within the housing internal volume in a first flow path to induce the first operating temperature concurrently with a second temperature-control fluid being directed laterally across at least a portion of the second circuit card subassembly within the housing internal volume in a second flow path to induce the second operating temperature.

A computer system includes a processor and a memory. The processor is located on a first circuit board having a first connector. The memory is located on a second circuit board having a second connector. The first circuit board and the second board are physically separated from each other but connect to each other through the connector. The processor and the memory are communicated to each other based on a differential signaling scheme.

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 ratting prevention structure is provided. Further, an electronic component module, an electrical connection box, and a wire harness which adopt the ratting prevention structure are provided. The electronic component module includes a cover having a rectangular opening portion, a connector block inserted into the opening portion of the cover, and an engagement mechanism engaging the block member with the opening portion of the cover. The rattling prevention structure is used to prevent rattling between the cover and the block member. In the rattling prevention structure, four pressing protrusions are formed at any one of four corner parts of the cover and four corner portions of the block member at the opening portion. The four pressing protrusions are configured to bend four walls of the cover inward while displacing the four corner parts of the cover outward.

Provided is an electrical junction box that enables easily checking the connection state of a connector terminal and a substrate. The electrical junction box includes: a box body; a substrate that is fitted to an inner portion of the box body; a connector terminal that passes through a side wall of the box body and is held thereby, and includes an inward end portion that is connected to the substrate; and a window hole that is formed in the side wall and enables visually checking a portion where the connector terminal is connected to the substrate.

A system and approach that may connect communication modules together in a daisy chain fashion as an expansion bus. A communication module may be connected with a data bus and a voltage bus to a baseboard having a controller. The communication module may have a multi-port universal serial bus hub connected to the data bus from the expansion connector, an electronic device connected to the hub and the voltage regulator. Another communication module having a similar structure as the first communication module may be connected to the first communication module via a data bus between the multiport hub of the first expansion module and a universal serial bus hub of the other communication module, and may have a voltage bus connected to the voltage bus of the first communication module. More communication modules may be connected in a daisy chain or serial fashion to a preceding module, and so on.