A semiconductor device A1 disclosed includes: a semiconductor element 10 having an element obverse face and element reverse face that face oppositely in a thickness direction z, with an obverse-face electrode 11 (first electrode 111) and a reverse-face electrode 12 respectively formed on the element obverse face and the element reverse face; a conductive member 22A opposing the element reverse face and conductively bonded to the reverse-face electrode 12; a conductive member 22B spaced apart from the conductive member 22A and electrically connected to the obverse-face electrode 11; and a lead member 51 having a lead obverse face 51a facing in the same direction as the element obverse face and connecting the obverse-face electrode 11 and the conductive member 22B. The lead member 51, bonded to the obverse-face electrode 11 via a lead bonding layer 321, includes a protrusion 521 protruding in the thickness direction z from the lead obverse face 51a. The protrusion 521 overlaps with the obverse-face electrode 11 as viewed in the thickness direction z. This configuration suppresses deformation of the connecting member to be pressed during sintering treatment.

A multi-chip package includes a field-programmable-gate-array (FPGA) integrated-circuit (IC) chip configured to perform a logic function based on a truth table, wherein the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip comprises multiple non-volatile memory cells therein configured to store multiple resulting values of the truth table, and a programmable logic block therein configured to select, in accordance with one of the combinations of its inputs, one from the resulting values into its output; and a memory chip coupling to the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip, wherein a data bit width between the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip and the memory chip is greater than or equal to 64.

A multi-chip package includes a field-programmable-gate-array (FPGA) integrated-circuit (IC) chip configured to perform a logic function based on a truth table, wherein the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip comprises multiple non-volatile memory cells therein configured to store multiple resulting values of the truth table, and a programmable logic block therein configured to select, in accordance with one of the combinations of its inputs, one from the resulting values into its output; and a memory chip coupling to the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip, wherein a data bit width between the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip and the memory chip is greater than or equal to 64.

A semiconductor device has a semiconductor die and an encapsulant deposited over the semiconductor die. A first conductive layer is formed with an antenna over a first surface of the encapsulant. A second conductive layer is formed with a ground plane over a second surface of the encapsulant with the antenna located within a footprint of the ground plane. A conductive bump is formed on the ground plane. A third conductive layer is formed over the first surface of the encapsulant. A fourth conductive layer is formed over the second surface of the encapsulant. A conductive via is disposed adjacent to the semiconductor die prior to depositing the encapsulant. The antenna is coupled to the semiconductor die through the conductive via. The antenna is formed with the conductive via between the antenna and semiconductor die. A PCB unit is disposed in the encapsulant.

A semiconductor device has a semiconductor die and an encapsulant deposited over the semiconductor die. A first conductive layer is formed with an antenna over a first surface of the encapsulant. A second conductive layer is formed with a ground plane over a second surface of the encapsulant with the antenna located within a footprint of the ground plane. A conductive bump is formed on the ground plane. A third conductive layer is formed over the first surface of the encapsulant. A fourth conductive layer is formed over the second surface of the encapsulant. A conductive via is disposed adjacent to the semiconductor die prior to depositing the encapsulant. The antenna is coupled to the semiconductor die through the conductive via. The antenna is formed with the conductive via between the antenna and semiconductor die. A PCB unit is disposed in the encapsulant.

Disclosed are EMI shielded packages, electronic device packages, and related methods. EMI shielded packages are formed by applying an insulating material to a first side of a substrate strip, separating the substrate strip into segments, adhering the insulating material of the segments to a solid conductor, applying a conductive paste around lateral sides of the segments, curing the conductive paste, and cutting through the conductive paste and the solid conductor to form the EMI packages. An electronic device package includes a substrate including electronic circuitry, an EMI shield, and an insulating material insulating the substrate from the EMI shield. The EMI shield includes a solid conductor adhered to the insulating material, and a cured conductive paste at least partially surrounding a lateral edge of the substrate. The cured conductive paste electrically connects the solid conductor to a conductive terminal in a lateral side of the substrate.

An electronic package including a middle patterned conductive layer, a first redistribution circuitry disposed on a first surface of the middle patterned conductive layer and a second redistribution circuitry disposed on a second surface of the middle patterned conductive layer is provided. The middle patterned conductive layer has a plurality of middle conductive pads. The first redistribution circuitry includes a first patterned conductive layer having a plurality of first conductive elements. Each of the first conductive elements has a first conductive pad and a first conductive via that form a T-shaped section. The second redistribution circuitry includes a second patterned conductive layer having a plurality of second conductive elements. Each of the second conductive elements has a second conductive pad and a second conductive via that form an inversed T-shaped section.

An electronic package including a middle patterned conductive layer, a first redistribution circuitry disposed on a first surface of the middle patterned conductive layer and a second redistribution circuitry disposed on a second surface of the middle patterned conductive layer is provided. The middle patterned conductive layer has a plurality of middle conductive pads. The first redistribution circuitry includes a first patterned conductive layer having a plurality of first conductive elements. Each of the first conductive elements has a first conductive pad and a first conductive via that form a T-shaped section. The second redistribution circuitry includes a second patterned conductive layer having a plurality of second conductive elements. Each of the second conductive elements has a second conductive pad and a second conductive via that form an inversed T-shaped section.

A microelectronic assembly having a first side and a second side opposite therefrom is disclosed. The microelectronic assembly may include a microelectronic element having a first face, a second face opposite the first face, a plurality of sidewalls each extending between the first and second faces, and a plurality of element contacts. The microelectronic assembly may also include an encapsulation adjacent the sidewalls of the microelectronic element. The microelectronic assembly may include electrically conductive connector elements each having a first end, a second end remote from the first end, and an edge surface extending between the first and second ends, wherein one of the first end or the second end of each connector element is adjacent the first side of the package. The microelectronic assembly may include a redistribution structure having terminals, the redistribution structure adjacent the second side of the package, the terminals being electrically coupled with the connector elements.

A microelectronic assembly having a first side and a second side opposite therefrom is disclosed. The microelectronic assembly may include a microelectronic element having a first face, a second face opposite the first face, a plurality of sidewalls each extending between the first and second faces, and a plurality of element contacts. The microelectronic assembly may also include an encapsulation adjacent the sidewalls of the microelectronic element. The microelectronic assembly may include electrically conductive connector elements each having a first end, a second end remote from the first end, and an edge surface extending between the first and second ends, wherein one of the first end or the second end of each connector element is adjacent the first side of the package. The microelectronic assembly may include a redistribution structure having terminals, the redistribution structure adjacent the second side of the package, the terminals being electrically coupled with the connector elements.