Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.

Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.

A package substrate film including a film substrate including upper and lower surfaces; a test pattern including an upper test line pattern extending on the upper surface of the film substrate; a lower test line pattern extending on the lower surface of the film substrate; a first test via pattern penetrating the film substrate and connecting the upper test line pattern to the lower test line pattern; a second test via pattern penetrating the film substrate outside the first test via pattern and connecting the upper test line pattern to the lower test line pattern; and a test pad between the first test via pattern and the second test via pattern, the test pad including first test pad at an outer side of the first test via pattern; and second test pad at an inner side of the second test via pattern and facing the first test pad.

A package substrate film including a film substrate including upper and lower surfaces; a test pattern including an upper test line pattern extending on the upper surface of the film substrate; a lower test line pattern extending on the lower surface of the film substrate; a first test via pattern penetrating the film substrate and connecting the upper test line pattern to the lower test line pattern; a second test via pattern penetrating the film substrate outside the first test via pattern and connecting the upper test line pattern to the lower test line pattern; and a test pad between the first test via pattern and the second test via pattern, the test pad including first test pad at an outer side of the first test via pattern; and second test pad at an inner side of the second test via pattern and facing the first test pad.

Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.

Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.

A semiconductor chip includes: a base substrate; a conductive pad on one surface of the base substrate; an insulating layer on the one surface of the base substrate and having an opening exposing a portion of the conductive pad; and a bump on the exposed portion of the conductive pad and on the insulating layer around the opening. The bump includes a plurality of concave portions corresponding to the opening and is arranged in a longitudinal direction of the bump.

A semiconductor chip includes: a base substrate; a conductive pad on one surface of the base substrate; an insulating layer on the one surface of the base substrate and having an opening exposing a portion of the conductive pad; and a bump on the exposed portion of the conductive pad and on the insulating layer around the opening. The bump includes a plurality of concave portions corresponding to the opening and is arranged in a longitudinal direction of the bump.

Provided herein may be an electronic device. The electronic device may include a substrate provided with a plurality of connecting pads including a first metal, a semiconductor chip on an area of the substrate, facing the connecting pads, and including a base substrate including a first surface facing the substrate, and a second surface opposite the first surface, a plurality of connecting terminals on the first surface, facing the connecting pads, and including a second metal, and a non-adhesive polymer layer on the second surface, and a conductive joining layer electrically connecting, and interposed between, respective ones of the connecting pads to the connecting terminals, and including a diffusion layer in which the first metal and the second metal are mixed.

Provided herein may be an electronic device. The electronic device may include a substrate provided with a plurality of connecting pads including a first metal, a semiconductor chip on an area of the substrate, facing the connecting pads, and including a base substrate including a first surface facing the substrate, and a second surface opposite the first surface, a plurality of connecting terminals on the first surface, facing the connecting pads, and including a second metal, and a non-adhesive polymer layer on the second surface, and a conductive joining layer electrically connecting, and interposed between, respective ones of the connecting pads to the connecting terminals, and including a diffusion layer in which the first metal and the second metal are mixed.