The present invention relates to an interposer substrate for interconnecting between active electronic componentry such as but not limited to a single or multiple integrated circuit chips in either a single or a combination and elements that could comprise of a mounting substrate, substrate module, a printed circuit board, integrated circuit chips or other substrates containing conductive energy pathways that service an energy utilizing load and leading to and from an energy source. The interposer will also possess a multi-layer, universal multi-functional, common conductive shield structure with conductive pathways for energy and EMI conditioning and protection that also comprise a commonly shared and centrally positioned conductive pathway or electrode of the structure that can simultaneously shield and allow smooth energy interaction between grouped and energized conductive pathway electrodes containing a circuit architecture for energy conditioning as it relates to integrated circuit device packaging. The invention can be employed between an active electronic component and a multilayer circuit card. A method for making the interposer is not presented and can be varied to the individual or proprietary construction methodologies that exist or will be developed.

The present invention relates to an interposer substrate for interconnecting between active electronic componentry such as but not limited to a single or multiple integrated circuit chips in either a single or a combination and elements that could comprise of a mounting substrate, substrate module, a printed circuit board, integrated circuit chips or other substrates containing conductive energy pathways that service an energy utilizing load and leading to and from an energy source. The interposer will also possess a multi-layer, universal multi-functional, common conductive shield structure with conductive pathways for energy and EMI conditioning and protection that also comprise a commonly shared and centrally positioned conductive pathway or electrode of the structure that can simultaneously shield and allow smooth energy interaction between grouped and energized conductive pathway electrodes containing a circuit architecture for energy conditioning as it relates to integrated circuit device packaging. The invention can be employed between an active electronic component and a multilayer circuit card. A method for making the interposer is not presented and can be varied to the individual or proprietary construction methodologies that exist or will be developed.

Disclosed are novel internal structures of energy conditioners having A, B, and G master electrodes, novel circuits including energy conditioners having A, B, and G master electrodes conductive structures, novel assemblies of internal structures and internal structures of energy conditioners having A, B, and G electrodes, and novel arrangements of energy conditioners having A, B, and G master electrodes on connection structures. Certain internal structures have conductive layers of A and B master electrodes in the same plane and conductive layers of the G master electrode extended beyond the periphery of the A and B layers except where the A and B layers have tabs extended to conductive integration structure integrating the A and B layers into respective A and B master electrodes.

Disclosed are energy conditioner structures, method of making and using them wherein the structure comprises a sequence of conductive layers including a first A layer, a G layer, and a first B layer; wherein said first A layer, said G layer, and said first B layer are each conductive, and are conductively isolated from one another in said energy conditioner structure; wherein said first A layer includes a first A layer main body and a first A layer tab, said first B layer includes a first B layer main body and a first B layer tab, and said G layer includes a G layer main body and a G layer first tab; wherein said G layer is in a plane between a plane containing said first A layer and a plane containing said first B layer; where the main body of at least one of said first A layer and said first B layer opposes a portion of said G layer main body; wherein two of said first A layer tab, said first B layer tab, and said G layer first tab are on a first side of said energy conditioner, and the remaining one of said first A layer tab, said first B layer tab, and said G layer first tab is on a second side of said energy conditioner, and said second side is opposite from said first side; and said method comprising applying electrical energy to one of said first A layer, said G layer, and said first B layer.

Disclosed are novel internal structures of energy conditioners (3a-3k) having A, B, and G master electrodes, novel assemblies of internal structures and internal structures of energy conditioners having A, B, and G electrodes, and novel arrangements of energy conditioners having A, B, and G master electrodes on connection structures.