A method produces a plurality of optoelectronic modules, and includes: A) providing a metallic carrier assembly with a plurality of carrier units; B) applying a logic chip, each having at least one integrated circuit, to the carrier units; C) applying emitter regions that generate radiation, which can be individually electrically controlled; D) covering the emitter regions and the logic chips with a protective material; E) overmolding the emitter regions and the logic chips so that a cast body is formed, which joins the carrier units, the logic chips and the emitter regions to one another; F) removing the protective material and applying electrical conductor paths to the upper sides of the logic chips and to a cast body upper side; and G) dividing the carrier assembly into the modules.

Certain aspects of the present disclosure provide apparatus and techniques for connecting packages for integrated circuits or packaged assemblies with other packages or modules using flex cables. An example packaged assembly for integrated circuits includes: a first integrated circuit (IC) package, a second IC package disposed above the first IC package, and a flex cable, wherein an end of the flex cable is connected to at least one of the first IC package or the second IC package.

A technique for interconnecting chips by using an interconnection substrate is disclosed. The interconnection substrate includes a base substrate, a first group of electrodes on the base substrate for a first chip to be mounted, and a second group of electrodes on the base substrate for a second chip to be mounted. The interconnection substrate further includes an interconnection layer that includes a first set of pads for the first chip, a second set of pads for the second chip, traces and an organic insulating material. The interconnection layer is disposed on the base substrate and located within a defined area on the base substrate between the first group of electrodes and the second group of the electrodes.

A technique for interconnecting chips by using an interconnection substrate is disclosed. The interconnection substrate includes a base substrate, a first group of electrodes on the base substrate for a first chip to be mounted, and a second group of electrodes on the base substrate for a second chip to be mounted. The interconnection substrate further includes an interconnection layer that includes a first set of pads for the first chip, a second set of pads for the second chip, traces and an organic insulating material. The interconnection layer is disposed on the base substrate and located within a defined area on the base substrate between the first group of electrodes and the second group of the electrodes.

A method produces a plurality of optoelectronic modules, and includes: A) providing a metallic carrier assembly with a plurality of carrier units; B) applying a logic chip, each having at least one integrated circuit, to the carrier units; C) applying emitter regions that generate radiation, which can be individually electrically controlled; D) covering the emitter regions and the logic chips with a protective material; E) overmolding the emitter regions and the logic chips so that a cast body is formed, which joins the carrier units, the logic chips and the emitter regions to one another; F) removing the protective material and applying electrical conductor paths to the upper sides of the logic chips and to a cast body upper side; and G) dividing the carrier assembly into the modules.

A technique for interconnecting chips by using an interconnection substrate is disclosed. The interconnection substrate includes a base substrate, a first group of electrodes on the base substrate for a first chip to be mounted, and a second group of electrodes on the base substrate for a second chip to be mounted. The interconnection substrate further includes an interconnection layer that includes a first set of pads for the first chip, a second set of pads for the second chip, traces and an organic insulating material. The interconnection layer is disposed on the base substrate and located within a defined area on the base substrate between the first group of electrodes and the second group of the electrodes.

A technique for interconnecting chips by using an interconnection substrate is disclosed. The interconnection substrate includes a base substrate, a first group of electrodes on the base substrate for a first chip to be mounted, and a second group of electrodes on the base substrate for a second chip to be mounted. The interconnection substrate further includes an interconnection layer that includes a first set of pads for the first chip, a second set of pads for the second chip, traces and an organic insulating material. The interconnection layer is disposed on the base substrate and located within a defined area on the base substrate between the first group of electrodes and the second group of the electrodes.

The semiconductor device of the present invention is a semiconductor device in which a first semiconductor chip including a first field effect transistor for a high-side switch, a second semiconductor chip including a second field effect transistor for a low-side switch, and a third semiconductor chip including a circuit that controls each of the first and second semiconductor chips are sealed with a sealing portion. A lead electrically connected to a pad of the first semiconductor chip for a source of the first field effect transistor and a lead electrically connected to a back-surface electrode of the second semiconductor chip for a drain of the second field effect transistor are disposed on the same side of the sealing portion in a plan view.

The semiconductor device of the present invention is a semiconductor device in which a first semiconductor chip including a first field effect transistor for a high-side switch, a second semiconductor chip including a second field effect transistor for a low-side switch, and a third semiconductor chip including a circuit that controls each of the first and second semiconductor chips are sealed with a sealing portion. A lead electrically connected to a pad of the first semiconductor chip for a source of the first field effect transistor and a lead electrically connected to a back-surface electrode of the second semiconductor chip for a drain of the second field effect transistor are disposed on the same side of the sealing portion in a plan view.