Four parts of a unity is described here, centered around the multi-tier conductive circuits. The detachable production platform is a prerequisite for manufacturing of these circuits as described. The solder-dispenser is necessary if the circuits are made of anything but magnetic metal powder, or if the means for containing solder material are made solid, and the device-dispenser replaces conventional pick-n-place machines to provide devices to a circuit much quicker and much cheaper.

The multi-tier conductive circuit that is the central idea and the final product of the presented innovations is highly flexible and highly cost efficient.

The trend of miniaturizing all kinds of electronic equipments has been the outset for these innovations and it is our firm belief that all the industry could benefit highly from such a circuit.

Microelectronic die packages, stacked systems of die packages, and methods of manufacturing them are disclosed herein. In one embodiment, a system of stacked packages includes a first die package having a bottom side, a first dielectric casing, and first metal leads; a second die package having a top side attached to the bottom side of the first package, a dielectric casing with a lateral side, and second metal leads aligned with and projecting towards the first metal leads and including an exterior surface and an interior surface region that generally faces the lateral side; and metal solder connectors coupling individual first leads to individual second leads. In a further embodiment, the individual second leads have an L shape and physically contact corresponding individual first leads. In another embodiment, the individual second leads have a C shape and include a tiered portion that projects towards the lateral side of the second casing.

A microelectronic unit can include a carrier structure having a front surface, a rear surface remote from the front surface, and a recess having an opening at the front surface and an inner surface located below the front surface of the carrier structure. The microelectronic unit can also include a microelectronic element having a top surface adjacent the inner surface, a bottom surface remote from the top surface, and a plurality of contacts at the top surface. The microelectronic unit can also include terminals electrically connected with the contacts of the microelectronic element. The terminals can be electrically insulated from the carrier structure. The microelectronic unit can also include a dielectric region contacting at least the bottom surface of the microelectronic element. The dielectric region can define a planar surface located coplanar with or above the front surface of the carrier structure.

Microelectronic die packages, stacked systems of die packages, and methods of manufacturing them are disclosed herein. In one embodiment, a system of stacked packages includes a first die package having a bottom side, a first dielectric casing, and first metal leads; a second die package having a top side attached to the bottom side of the first package, a dielectric casing with a lateral side, and second metal leads aligned with and projecting towards the first metal leads and including an exterior surface and an interior surface region that generally faces the lateral side; and metal solder connectors coupling individual first leads to individual second leads. In a further embodiment, the individual second leads have an L shape and physically contact corresponding individual first leads. In another embodiment, the individual second leads have a C shape and include a tiered portion that projects towards the lateral side of the second casing.

A reconstituted semiconductor package and a method of making a reconstituted semiconductor package are described. An array of die-attach substrates is formed onto a carrier. A semiconductor device is mounted onto a first surface of each of the die-attach substrates. An interposer substrate is mounted over each of the semiconductor devices. The interposer substrates are electrically connected to the first surface of the respective die-attach substrates. A molding compound is filled in open spaces within and between the interposer substrates mounted to their respective die-attach substrates to form an array of reconstituted semiconductor packages. Electrical connections are mounted to a second surface of the die-attach substrates. The array of reconstituted semiconductor packages is singulated through the molding compound between each of the die-attach substrates and respective mounted interposer substrates.

A package structure and method of making the same is provided. A through via is formed on a substrate, the through via extending through a molding material. An upper surface of the molding material is recessed from an upper surface of the through via. A dielectric layer is deposited over the through via and the molding material. The dielectric layer has a first upper surface with a first variation in height between a first area disposed over the through via and a second area disposed over the molding material. Exposure processes are performed on the dielectric layer. The dielectric layer is developed. After the developing, the dielectric layer has a second upper surface with a second variation in height between the first area and the second area. The first variation is greater than the second variation.

Embodiments disclosed herein include electronic package and methods of forming such packages. In an embodiment, an electronic package comprises a mold layer and a first die embedded in the mold layer. In an embodiment, the first die comprises first pads at a first pitch and second pads at a second pitch. In an embodiment, the electronic package further comprises a second die embedded in the mold layer, where the second die comprises third pads at the first pitch and fourth pads at the second pitch. In an embodiment, a bridge die is embedded in the mold layer, and the bridge die electrically couples the second pads to the fourth pads.

A process for manufacturing a surface-mount electronic device includes forming a plurality of preliminary contact regions of a sinterable material on a supporting structure, the supporting structure being of a soluble type. A chip including a semiconductor body is mechanically coupled to the supporting structure. The sinterable material is sintered such that each preliminary contact region forms a corresponding sintered preliminary contact, and the chip and the plurality of preliminary contact regions are coated with a dielectric coating region, and the supporting structure is removed using a jet of liquid.

A method includes forming a multi-stacked electronic device having two or more electronic components, each of the electronic components includes a leadframe, the leadframes of each electronic component are physically joined together using a non-solder metal joining process to form a joint, and the joint is located outside a solder connection region.

A method includes forming a multi-stacked electronic device having two or more electronic components, each of the electronic components includes a leadframe, the leadframes of each electronic component are physically joined together using a non-solder metal joining process to form a joint, and the joint is located outside a solder connection region.