An electronic assembly includes an electronic package including a package substrate and an integrated circuit component mounted to an upper surface. The electronic package includes upper package contacts electrically connected to the integrated circuit component. The electronic assembly includes an interposer assembly including an array of compressible interposer contacts each having upper and lower mating interfaces. The interposer assembly defining a separable interface. The electronic assembly includes optical modules coupled to the separable interface of the interposer assembly and having an optical module substrate having module contacts and an optical engine mounted to the optical module substrate electrically connected to the module contacts. The optical module is mounted to the interposer assembly such that the module contacts are electrically connected to the upper mating interfaces of the interposer contacts. Each optical module includes at least one optical fiber terminated to the optical engine.

A hermetically-sealed edge-connect header that can withstand high temperatures, high pressures (or high vacuum levels), and high vibration environments, along with two corresponding connectors are disclosed. After brazing the edge-connect header components, the assembly is machined to form a slot with a portion of each of a plurality of electrical conductors removed in the machining process, resulting in a header with a high pin density. During the process of mating the first connector design to the edge-connect header, a plurality of wipers in the connector deflect, thereby causing the wipers to extend from the connector and contact the corresponding electrical conductors in the header. During the process of mating the second connector design to the edge-connect header, each of a plurality of wipers formed of low-mass, compliant metal wool, forms multiple contact points with a corresponding electrical conductor in the header.

A hermetically-sealed edge-connect header that can withstand high temperatures, high pressures (or high vacuum levels), and high vibration environments, along with two corresponding connectors are disclosed. After brazing the edge-connect header components, the assembly is machined to form a slot with a portion of each of a plurality of electrical conductors removed in the machining process, resulting in a header with a high pin density. During the process of mating the first connector design to the edge-connect header, a plurality of wipers in the connector deflect, thereby causing the wipers to extend from the connector and contact the corresponding electrical conductors in the header. During the process of mating the second connector design to the edge-connect header, each of a plurality of wipers formed of low-mass, compliant metal wool, forms multiple contact points with a corresponding electrical conductor in the header.

A base of a connector defines an accommodation portion for accommodating a card-type device. The base has holding portions with surfaces directed to the accommodation portion. The holding portions hold held portions of terminals 40. Heat conductive members are provided on the surfaces of the holding portions. The heat conductive members are sandwiched between the card-type device and the holding portions when the card-type device is connected to the connector 10. In this way, heat conductive paths, which include the conductive members, are formed between the card-type device and held portions of the terminals 40.

A hermetically-sealed edge-connect header that can withstand high temperatures, high pressures (or high vacuum levels), and high vibration environments, along with two corresponding connectors are disclosed. After brazing the edge-connect header components, the assembly is machined to form a slot with a portion of each of a plurality of electrical conductors removed in the machining process, resulting in a header with a high pin density. During the process of mating the first connector design to the edge-connect header, a plurality of wipers in the connector deflect, thereby causing the wipers to extend from the connector and contact the corresponding electrical conductors in the header. During the process of mating the second connector design to the edge-connect header, each of a plurality of wipers formed of low-mass, compliant metal wool, forms multiple contact points with a corresponding electrical conductor in the header.

A hermetically-sealed edge-connect header that can withstand high temperatures, high pressures (or high vacuum levels), and high vibration environments, along with two corresponding connectors are disclosed. After brazing the edge-connect header components, the assembly is machined to form a slot with a portion of each of a plurality of electrical conductors removed in the machining process, resulting in a header with a high pin density. During the process of mating the first connector design to the edge-connect header, a plurality of wipers in the connector deflect, thereby causing the wipers to extend from the connector and contact the corresponding electrical conductors in the header. During the process of mating the second connector design to the edge-connect header, each of a plurality of wipers formed of low-mass, compliant metal wool, forms multiple contact points with a corresponding electrical conductor in the header.

Apparatuses, systems and methods associated with connector design for mating with integrated circuit packages are disclosed herein. In embodiments, a connector for mating with an integrated circuit (IC) package may include a housing with a recess to receive a portion of the IC package and a contact coupled to the housing and that extends into the recess. The contact may include a main body that extends from the housing into the recess and a curved portion that extends from an end of the main body, wherein the curved portion loops back and contacts the main body. Other embodiments may be described and/or claimed.

Apparatuses, systems and methods associated with connector design for mating with integrated circuit packages are disclosed herein. In embodiments, a connector for mating with an integrated circuit (IC) package may include a housing with a recess to receive a portion of the IC package and a contact coupled to the housing and that extends into the recess. The contact may include a main body that extends from the housing into the recess and a curved portion that extends from an end of the main body, wherein the curved portion loops back and contacts the main body. Other embodiments may be described and/or claimed.

A spring clip for a flat flexible cable includes a first beam and a second beam connected to the first beam and resiliently deflectable toward the first beam. The second beam has a first contact bend extending toward the first beam. The flat flexible cable is positioned between the first beam and the second beam and the first contact bend abuts a conductor exposed through an insulation material of the flat flexible cable to electrically connect the spring clip with the conductor.

Aspects of the disclosure provide a package system that includes a first integrated circuit (IC) package and a second IC package. The first IC package includes a first IC chip mounted on a first substrate-chip surface of a first package substrate. The first package substrate includes first near-conductive layers that are closer to the first substrate-chip surface than first far-conductive layers. The second IC package includes a second IC chip mounted on a second substrate-chip surface of a second package substrate. The second package substrate includes second near-conductive layers that are closer to the second substrate-chip surface than second far-conductive layers. A first contact structure on the first substrate-chip surface and a second contact structure on the second substrate-chip surface electrically couple the first IC chip with the second IC chip through electrical connections in the first and second near-conductive layers.