An electronic device includes: a first substrate having a first surface and a second surface opposite from the first surface; a second substrate facing the first surface; driven elements provided at the second substrate; a drive circuit facing the second surface; a first interconnect provided at the first surface; a second interconnect provided at the second surface; a through-substrate interconnection part penetrating the first substrate in a thickness direction thereof; a first bump part; and a second bump part. The drive circuit is capable of outputting drive signals for driving the driven elements. The through-substrate interconnection part electrically connects the first interconnect and the second interconnect. The first bump part electrically connects the first interconnect and the driven elements. The second bump part electrically connects the second interconnect and the drive circuit. The through-substrate interconnection part has an electrical resistance lower than an electrical resistance of the second bump part.

A semiconductor package structure includes a first semiconductor die having an active surface and a passive surface opposite to the active surface, a conductive element leveled with the first semiconductor die, a first redistribution layer (RDL) being closer to the passive surface than to the active surface, a second RDL being closer to the active surface than to the passive surface, and a second semiconductor die over the second RDL and electrically coupled to the first semiconductor die through the second RDL. A first conductive path is established among the first RDL, the conductive element, the second RDL, and the active surface of the first semiconductor die.

A semiconductor die assembly in accordance with an embodiment of the present technology includes first and second semiconductor dies spaced apart from one another. The first semiconductor die has a major surface with non-overlapping first and second regions. The semiconductor die assembly further includes an array of first pillars extending heightwise from the first region of the major surface of the first semiconductor die toward the second semiconductor die. Similarly, the semiconductor die assembly includes an array of second pillars extending heightwise from the second region of the major surface of the first semiconductor die toward the second semiconductor die. The first and second pillars have different lateral densities and different average widths. The latter difference at least partially offsets an effect of the former difference on relative metal deposition rates of an electrochemical plating process used to form the first and second pillars.

An electronic device includes: a first substrate having a first surface and a second surface opposite from the first surface; a second substrate facing the first surface; driven elements provided at the second substrate; a drive circuit facing the second surface; a first interconnect provided at the first surface; a second interconnect provided at the second surface; a through-substrate interconnection part penetrating the first substrate in a thickness direction thereof; a first bump part; and a second bump part. The drive circuit is capable of outputting drive signals for driving the driven elements. The through-substrate interconnection part electrically connects the first interconnect and the second interconnect. The first bump part electrically connects the first interconnect and the driven elements. The second bump part electrically connects the second interconnect and the drive circuit. The through-substrate interconnection part has an electrical resistance lower than an electrical resistance of the second bump part.

A semiconductor package structure includes a first semiconductor die having an active surface and a passive surface opposite to the active surface, a conductive element leveled with the first semiconductor die, a first redistribution layer (RDL) being closer to the passive surface than to the active surface, a second RDL being closer to the active surface than to the passive surface, and a second semiconductor die over the second RDL and electrically coupled to the first semiconductor die through the second RDL. A first conductive path is established among the first RDL, the conductive element, the second RDL, and the active surface of the first semiconductor die.

A multi-chip module includes a first semiconductor component including a first set of connections having a first pitch dimension and at least a second set of connections having a second pitch dimension, wherein the first pitch dimension is smaller than the second pitch dimension. The multi-chip module further includes a second semiconductor component interconnected with the first set of connections of the first semiconductor component. The multi-chip module further includes at least a third semiconductor component interconnected with the second set of connections of the first semiconductor component and wherein a surface of the third semiconductor component is adhered to a surface of the second semiconductor component, wherein the surfaces at least partially overlap one another.

A multi-chip module includes a first semiconductor component including a first set of connections having a first pitch dimension and at least a second set of connections having a second pitch dimension, wherein the first pitch dimension is smaller than the second pitch dimension. The multi-chip module further includes a second semiconductor component interconnected with the first set of connections of the first semiconductor component. The multi-chip module further includes at least a third semiconductor component interconnected with the second set of connections of the first semiconductor component and wherein a surface of the third semiconductor component is adhered to a surface of the second semiconductor component, wherein the surfaces at least partially overlap one another.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a first semiconductor die, an insulating encapsulation laterally encapsulating the first semiconductor die, and a redistribution structure disposed on the first semiconductor die and the insulating encapsulation. The first semiconductor die includes a first contact region and a first non-contact region in proximity to the first contact region. The first semiconductor die includes a first electrical connector disposed on the first contact region and a first dummy conductor disposed on the first non-contact region, and the first electrical connector is electrically connected to a first integrated circuit (IC) component in the first semiconductor die. The first electrical connector is electrically connected to the redistribution structure, and the first dummy conductor is electrically insulated from the first IC component in the first semiconductor die and the redistribution structure.

A chip package structure includes a chip package layer and at least one conductive structure layer. The chip package layer includes at least one chip and an encapsulant. The chip has an upper surface, and the encapsulant is used to encapsulate the chip and expose the upper surface. The conductive structure layer includes a plurality of first conductive pillars and a plurality of second conductive pillars. The first conductive pillars are disposed on the upper surface, the second conductive pillars are disposed on the upper surface and located between an edge of the upper surface and the first conductive pillars. A density of the second conductive pillars along an extending direction of the edge is greater than or equal to 1.2 times of a density of the first conductive pillars along the extending direction of the edge.

Embodiments herein relate to a semiconductor package or a semiconductor package structure that includes an interposer with opposing first and second sides. A memory and a processing unit may be coupled with the second side of the interposer, and the first side of the interposer may be to couple with the substrate. The processing unit and memory may be communicatively coupled with one another and the substrate by the interposer. Other embodiments may be described or claimed.