A flat electric cable connection structure includes a flat electric cable, terminal fittings, and alleviation portions. The flat electric cable includes, at one end portion thereof, a plurality of separate strip-shaped portions in which a plurality of band-shaped conductor paths are individually separated. The terminal fittings include conductor path connecting portions connected to band-shaped conductor paths of the separate band-shaped portions. The alleviation portions include bypass mechanisms that bypass an arrangement route of the flat electric cable from the conductor path connecting portions of the terminal fittings to a lead-out portion.

An electronic device including a stacked connector assembly is provided. In some embodiments, the electronic device includes: a first printed circuit board; a first electronic board-to-board connector mounted to the first printed circuit board; a second printed circuit board; a second electronic board-to-board connector mounted to the second printed circuit board and connected to the first electronic board-to-board connector; a first stacked connector mounted to the second printed circuit board; a second stacked connector connected to the first stacked connector; and a biasing member. The biasing member may bias the first board-to-board electronic connector together with the second electronic board-to-board connector, and the first stacked connector together with the second stacked connector.

An electronic device including a stacked connector assembly is provided. In some embodiments, the electronic device includes: a first printed circuit board; a first electronic board-to-board connector mounted to the first printed circuit board; a second printed circuit board; a second electronic board-to-board connector mounted to the second printed circuit board and connected to the first electronic board-to-board connector; a first stacked connector mounted to the second printed circuit board; a second stacked connector connected to the first stacked connector; and a biasing member. The biasing member may bias the first board-to-board electronic connector together with the second electronic board-to-board connector, and the first stacked connector together with the second stacked connector.

A connector includes a housing, a switch, a set portion, and a contact terminal. An insertion port and a guide hole are formed in the housing. A flat cable is inserted in the insertion port. The guide hole is a through hole passing through the housing in a direction perpendicular to an insertion direction of the flat cable. When the switch moves along the guide hole in a removal direction opposed to the insertion direction, the set portion protrudes outside the housing from the insertion port. A connection portion of the flat cable is set on the set portion. When the switch moves along the guide hole in the insertion direction, the set portion is stored in an inner space of the housing. The contact terminal contacts and presses, in the inner space, a conductor provided in the connection portion.

A connector assembly comprises a first connector and a second connector which are mateable with each other along a front-rear direction. The first connector comprises two or more sub-connectors and a housing. The sub-connectors are configured to be connected to two or more branching end portions of a single flexible printed circuits (FPC) board, respectively. The housing holds each of the sub-connectors. Each of the sub-connectors is floatable relative to the housing. The second connector comprises two or more mating portions which correspond to the sub-connectors, respectively. Each of the sub-connectors is mateable with a corresponding one of the mating portions.

A connector structure includes a first metal housing, a flexible flat transmission component and a second metal housing. The first metal housing includes an installation portion and two guiding portions disposed on two sides of the installation portion. Each guiding portion includes a bottom section, a top section opposite to the bottom section, and a bending section connected to the bottom section and the top section. A slot is formed on the bottom section, and an extending section extends from the top section and toward the bottom section to engage inside the slot. The flexible flat transmission component is disposed on the installation portion and includes a plurality of contacts. The second metal housing is assembled with the first metal housing and covers the flexible flat transmission component, and the plurality of contacts exposes out of the second metal housing.

A connector structure includes a first metal housing, a flexible flat transmission component and a second metal housing. The first metal housing includes an installation portion and two guiding portions disposed on two sides of the installation portion. Each guiding portion includes a bottom section, a top section opposite to the bottom section, and a bending section connected to the bottom section and the top section. A slot is formed on the bottom section, and an extending section extends from the top section and toward the bottom section to engage inside the slot. The flexible flat transmission component is disposed on the installation portion and includes a plurality of contacts. The second metal housing is assembled with the first metal housing and covers the flexible flat transmission component, and the plurality of contacts exposes out of the second metal housing.

Embodiments provide for a method for pluggable Land Grid Array (LGA) socket for high density interconnects. A method includes inserting an electrical-to-optical transceiver into an opening of a channel housing that is positioned above a land grid array connector located on an electrical package. After the electrical-to-optical transceiver is inserted into the channel housing, a tapered opening remains between an upper portion of the channel housing above the electrical-to-optical transceiver, wherein a gap of the tapered opening decreases progressively starting from the opening. The method includes inserting a conductive wedge into the gap of the tapered opening prior to communications through the electrical-to-optical transceiver between a component on the electrical package and a component external to the electrical package.

Embodiments provide for a method for pluggable Land Grid Array (LGA) socket for high density interconnects. A method includes inserting an electrical-to-optical transceiver into an opening of a channel housing that is positioned above a land grid array connector located on an electrical package. After the electrical-to-optical transceiver is inserted into the channel housing, a tapered opening remains between an upper portion of the channel housing above the electrical-to-optical transceiver, wherein a gap of the tapered opening decreases progressively starting from the opening. The method includes inserting a conductive wedge into the gap of the tapered opening prior to communications through the electrical-to-optical transceiver between a component on the electrical package and a component external to the electrical package.

An electrical connection device has a first insulating body. A strip-shaped first conductor is accommodated in the first insulating body. The first conductor as a whole is arranged horizontally to electrically connect backward with a first docking component. A bottom surface of the first conductor has a front edge, and a contact area extends backward from the front edge. A second docking component includes a second conductor located below the first conductor. The second conductor has a front end, a rear end, and a top surface connecting the front and rear ends. An elastic body is located above the first conductor and downwardly abuts the first conductor. A pressing piece provides a downward force to make the first conductor downwardly abut the second conductor.