The present invention relates to a chip-on film type semiconductor package including an integrated circuit chip, a printed circuit board layer, an outer lead bonder pad, and a graphite layer, in which the integrated circuit chip is connected to one surface of the printed circuit board layer directly or by means of a mounting element, the outer lead bonder pad is located on one surface of the printed circuit board layer, and the graphite layer is laminated on an opposite surface of the printed circuit board layer and a display device including the same.

A semiconductor packaging structure for packaging a semiconductor chip is disclosed, the semiconductor chip comprises at least two electrodes, each of the at least two electrodes comprises at least one electrode opening, and the packaging structure comprises: a packaging chassis, provided with at least two pin electrodes respectively corresponding to the at least two electrodes; and at least two extended electrodes, each of the at least two extended electrodes being electrically connected to one of the at least two pin electrodes, and comprising at least one conductive pillar for inserting into the at least one electrode opening formed on one of the at least two electrodes.

A method for forming a semiconductor package is disclosed herein. The method includes forming a package substrate having a first major surface and a second major surface opposite to the first major surface. The package substrate includes a recess region below the first major surface defined with a die region and a non-die region surrounding the die region. A semiconductor die is disposed in the die region within the recess region. A dam structure is disposed within the recess region. The dam structure surrounds the semiconductor die and extends upwardly to a height below the first major surface of the package substrate. The method also includes dispensing a liquid encapsulant material into the recess region. The liquid encapsulant material is surrounded by the dam structure and extends upwardly to a height below the height of the dam structure. A package lid is attached to the package substrate.

An improved method for forming a semiconductor package is disclosed herein. The method includes forming a multi-layer package substrate having a first major surface and a second major surface opposite to the first major surface. The package substrate comprises a recess region. A semiconductor die is attached to the die region within the recess region. A dam structure is formed within the recess region. The dam structure surrounds the semiconductor die and extends upward to a height below the first major surface of the package substrate. A liquid encapsulant material is dispensed into the recess region. The liquid encapsulant material is surrounded by the dam structure. The liquid encapsulant extends upwardly to a height below the height of the dam structure. A package lid is attached to the package substrate.

A method of manufacturing a through-hole electrode substrate includes forming a plurality of through-holes in a substrate, forming a plurality of through-hole electrodes by filling a conductive material into the plurality of through-holes, forming a first insulation layer on one surface of the substrate, forming a plurality of first openings which expose the plurality of through-hole electrodes corresponding to each of the plurality of through-hole electrodes, on the first insulation layer and correcting a position of the plurality of first openings using the relationship between a misalignment amount of a measured distance value of an open position of a leaning through-hole among the plurality of through-holes and of a design distance value of the open position of the leaning through-hole among the plurality of through-holes with respect to a center position of the substrate.

An electronic module includes an electronic part including a bottom surface and lands, the bottom surface including a first region and a third region surrounding the first region, the first lands being disposed in the third region, a printed wiring board including a main surface and second lands, the main surface including a second region and a fourth region surrounding the second region, the main surface facing the bottom surface of the electronic part, the second lands being disposed in the fourth region, solder bonding portions respectively bonding the first lands to the second lands, and a resin portion containing a cured product of a thermosetting resin and being in contact with the solder boding portions. A recess portion is provided in the second region. The resin portion is not provided in the recess portion.

An oscillator includes a vibration element, an oscillation circuit configured to oscillate the vibration element and output an oscillation signal, a temperature sensor, a temperature compensation circuit configured to compensate for a frequency temperature characteristic of the vibration element based on an output signal of the temperature sensor. The vibration element is within a first case having a first atmosphere, and the oscillation circuit, the temperature sensor, and the first case are within a second case having a second atmosphere, whereby the first atmosphere has a higher thermal conductivity than the second atmosphere.

A semiconductor packaging structure for packaging a semiconductor chip is disclosed, the semiconductor chip comprises at least two electrodes, each of the at least two electrodes comprises at least one electrode opening, and the packaging structure comprises: a packaging chassis, provided with at least two pin electrodes respectively corresponding to the at least two electrodes; and at least two extended electrodes, each of the at least two extended electrodes being electrically connected to one of the at least two pin electrodes, and comprising at least one conductive pillar for inserting into the at least one electrode opening formed on one of the at least two electrodes.

An improved method for forming a semiconductor package is disclosed herein. The method includes forming a multi-layer package substrate having a first major surface and a second major surface opposite to the first major surface. The package substrate comprises a recess region. A semiconductor die is attached to the die region within the recess region. A dam structure is formed within the recess region. The dam structure surrounds the semiconductor die and extends upward to a height below the first major surface of the package substrate. A liquid encapsulant material is dispensed into the recess region. The liquid encapsulant material is surrounded by the dam structure. The liquid encapsulant extends upwardly to a height below the height of the dam structure. A package lid is attached to the package substrate.

A method of manufacturing a through-hole electrode substrate includes forming a plurality of through-holes in a substrate, forming a plurality of through-hole electrodes by filling a conductive material into the plurality of through-holes, forming a first insulation layer on one surface of the substrate, forming a plurality of first openings which expose the plurality of through-hole electrodes corresponding to each of the plurality of through-hole electrodes, on the first insulation layer and correcting a position of the plurality of first openings using the relationship between a misalignment amount of a measured distance value of an open position of a leaning through-hole among the plurality of through-holes and of a design distance value of the open position of the leaning through-hole among the plurality of through-holes with respect to a center position of the substrate.