The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

A stacked package has plurality of chip packages stacked on active surfaces of each other, a dielectric layer, a redistribution layer and a plurality of external terminals. Each chip package has an exterior conductive element formed on the active surface. Each exterior conductive element has a cut edge exposed on at least one of the lateral side of the chip package. The dielectric layer, the redistribution layer and the external terminals are formed in sequence on the lateral side with the exposed cut edges to form the electrical connection between the cut edges, the redistribution layer and the external terminals. Therefore, the process for forming the electrical connections is simplified to enhance the reliability and the UPH for manufacturing the stacked package.

A stacked package has plurality of chip packages stacked on active surfaces of each other, a dielectric layer, a redistribution layer and a plurality of external terminals. Each chip package has an exterior conductive element formed on the active surface. Each exterior conductive element has a cut edge exposed on at least one of the lateral side of the chip package. The dielectric layer, the redistribution layer and the external terminals are formed in sequence on the lateral side with the exposed cut edges to form the electrical connection between the cut edges, the redistribution layer and the external terminals. Therefore, the process for forming the electrical connections is simplified to enhance the reliability and the UPH for manufacturing the stacked package.

A stacked package has plurality of chip packages stacked on active surfaces of each other, a dielectric layer, a redistribution layer and a plurality of external terminals. Each chip package has an exterior conductive element formed on the active surface. Each exterior conductive element has a cut edge exposed on at least one of the lateral side of the chip package. The dielectric layer, the redistribution layer and the external terminals are formed in sequence on the lateral side with the exposed cut edges to form the electrical connection between the cut edges, the redistribution layer and the external terminals. Therefore, the process for forming the electrical connections is simplified to enhance the reliability and the UPH for manufacturing the stacked package.

A stacked package has plurality of chip packages stacked on active surfaces of each other, a dielectric layer, a redistribution layer and a plurality of external terminals. Each chip package has an exterior conductive element formed on the active surface. Each exterior conductive element has a cut edge exposed on at least one of the lateral side of the chip package. The dielectric layer, the redistribution layer and the external terminals are formed in sequence on the lateral side with the exposed cut edges to form the electrical connection between the cut edges, the redistribution layer and the external terminals. Therefore, the process for forming the electrical connections is simplified to enhance the reliability and the UPH for manufacturing the stacked package.

In one embodiment, a semiconductor package includes a semiconductor die having conductive pads. A lead frame is directly connected to the conductive pads using an electrochemically formed layer or a conductive adhesive layer thereby facilitating an electrical connection between the conductive pads of the semiconductor die and the lead frame without using separate wire bonds or conductive bumps.

In one embodiment, a semiconductor package includes a semiconductor die having conductive pads. A lead frame is directly connected to the conductive pads using an electrochemically formed layer or a conductive adhesive layer thereby facilitating an electrical connection between the conductive pads of the semiconductor die and the lead frame without using separate wire bonds or conductive bumps.