A method of biasing a guard ring structure includes biasing a gate of a MOS transistor to a first bias voltage level, biasing first and second S/D regions of the MOS transistor to a power domain voltage level, biasing a gate of the guard ring structure to a second bias voltage level, and biasing first and second heavily doped regions of the guard ring structure to the power domain voltage level. Each of the first and second S/D regions has a first doping type, each of the first and second heavily doped regions has a second doping type different from the first doping type, and each of the first and second S/D regions and the first and second heavily doped regions is positioned in a substrate region having the second doping type.

An integrated circuit package structure is provided that includes a chip carrier substrate, at least one processor die provided on the chip carrier substrate, a plurality of lateral escape wiring lines connected to and extending away from the at least one processor die, and a plurality of chips at least partially surrounding the processor die, at least one of the chips overlapping with at least one of the lateral escape wiring lines in a plan view. An interconnect structure of the chips includes at least one vertical power feed structure that is configured and positioned not to intersect with the lateral escape wiring lines in the plan view.

An electronic device package is described. The electronic device package includes one or more dies. The electronic device package includes an interposer coupled to the one or more dies. The electronic device package also includes a package substrate coupled to the interposer. The electronic device package includes a plurality of through-silicon vias (TSVs) in at least one die of the one or more dies, or the interposer, or both. The electronic device package includes a passive equalizer structure communicatively coupled to a TSV pair in the plurality of TSVs. The passive equalizer structure is operable to minimize a level of insertion loss variation in the TSV pair.

Methods and apparatus for inductor and transformer semiconductor devices using hybrid bonding technology are disclosed. An example semiconductor device includes a first standoff substrate; a second standoff substrate adjacent the first standoff substrate; and a conductive layer adjacent at least one of the first standoff substrate or the second standoff substrate.

A package comprising a substrate and an integrated device coupled to the substrate. The substrate includes at least one dielectric layer, a plurality of interconnects comprising a first interconnect and a second interconnect, a capacitor located at least partially in the substrate, the capacitor comprising a first terminal and a second terminal, a first solder interconnect coupled to a first side surface of the first terminal and the first interconnect, and a second solder interconnect coupled to a second side surface of the second terminal and the second interconnect.

A semiconductor device includes a first terminal, a second terminal positioned away from the first terminal, a first resistive segment coupled between the first terminal and the second terminal, a third terminal positioned away from the first terminal and the second terminal, a second resistive segment coupled between the second terminal and third terminal, a first floating plate disposed physically proximate the first resistive segment and including a first end coupled to one of the first terminal and the second terminal, and a second floating plate disposed physically proximate the second resistive segment and including a first end coupled to one of the second terminal and the third terminal.

Various disclosed embodiments include a substrate, a first interposer coupled to the substrate and to a first semiconductor device die, and a second interposer coupled to the substrate and to a second semiconductor device die. The first semiconductor device die may be a serializer/de-serializer die and the first semiconductor device die coupled to the first interposer may be located proximate to a sidewall of the substrate. In certain embodiments, the second semiconductor device die may be a system-on-chip die. In further embodiments, the second interposer may also be coupled to high bandwidth memory die. Placing a serializer/de-serializer die proximate to a sidewall of a substrate allows a length of electrical pathways to be reduced, thus reducing impedance and RC delay. The use of smaller, separate, interposers also reduces complexity of fabrication of interposers and similarly lowers impedance associated with redistribution interconnect structures associated with the interposers.

An electronic device includes a multilevel lamination structure having a core layer, dielectric layers and conductive features formed in metal layers on or between respective ones or pairs of the dielectric layers. The core layer and the dielectric layers extend in respective planes of orthogonal first and second directions and are stacked along an orthogonal third direction. The conductive features include a first patterned conductive feature having multiple conductive turns in each of a first pair of the metal layers to form a first winding having a first turn and a final turn adjacent to one another in the same metal layer of the first pair, and a second patterned conductive feature having multiple conductive turns in a second pair of the metal layers to form a second winding having a first turn and a final turn.

In a described example, an integrated circuit includes: a semiconductor substrate having a first surface and an opposite second surface; at least one dielectric layer overlying the first surface of the semiconductor substrate; at least one inductor coil in the at least one dielectric layer with a plurality of coil windings separated by coil spaces, the at least one inductor coil lying in a plane oriented in a first direction parallel to the first surface of the semiconductor substrate, the at least one inductor coil electrically isolated from the semiconductor substrate by a portion of the at least one dielectric layer; and trenches extending into the semiconductor substrate in a second direction at an angle with respect to the first direction, the trenches underlying the inductor coil and filled with dielectric replacement material.

A microelectronic device has a first die attached to a first die pad, and a second die attached to a second die pad. A magnetically permeable member is attached to a first coupler pad and a second coupler pad. A coupler component is attached to the magnetically permeable member. The first die pad, the second die pad, the first coupler pad, the second coupler pad, and the magnetically permeable member are electrically conductive. The first coupler pad is electrically isolated from the first die, from the second coupler pad, and from external leads of the microelectronic device. The second coupler pad is electrically isolated from the first die and from the external leads. The first die and the second die are electrically coupled to the coupler component. A package structure contains at least portions of the components of the microelectronic device and extends to the external leads.