Abstract: A novel semiconductor chip scale package encapsulates semiconductor chip on the device side, the non-device side, and the four edges with a mold compound. One process to fabricate such a semiconductor chip scale package involves forming trenches on the surface of a wafer around the chips and filling the trenches and covering the device side of the chips with a first mold compound. The wafer is subsequently thinned from the non-device side until the bottom portion of the trenches and the mold compound in the portion are also removed. The thinning process creates a plane that contains the back side of the chips and the mold compound exposed in the trench. This plane is subsequently covered with a second mold compound.

Abstract: A novel semiconductor chip scale package encapsulates a semiconductor chip on the device side, the non-device side, and the four edges with a mold compound. One process to fabricate such a semiconductor chip scale package involves forming trenches on the surface of a wafer around the chips and filling the trenches and covering the device side of the chips with a first mold compound. The wafer is subsequently thinned from the non-device side until the bottom portion of the trenches and the mold compound in the portion are also removed. The thinning process creates a plane that contains the back side of the chips and the mold compound exposed in the trench. This plane is subsequently covered with a second mold compound.

Abstract: Semiconductor devices are described that have an extended under ball metallization configured to mitigate dielectric layer cracking due to stress, particularly stress caused by CTE mismatch during thermal cycling tests, dynamic deformation during drop tests, or cyclic bending tests, and so on. In an implementation, the semiconductor package devices include an integrated circuit chip having a solder ball and under ball metallization, formed on the integrated circuit chip, which is configured to receive the solder ball so that the solder ball and the under ball metallization have a contact area there between, wherein the area of the under ball metallization is area greater than the contact area.

Abstract: The present invention has various aspects relating to the maximization of current carrying capacity of wafer level packaged chip scale solder pad mounted integrated circuits. In one aspect, the solder pad areas are maximized by using rectangular solder pads spaced as close together as reliable mounting to a circuit board will allow. In another aspect, multiple contact pads may be used for increasing the current capacity without using contact pads of different areas. In still another aspect, vias are used to directly connect one lead of high current component or components to a contact pad directly above that component, and to route a second lead of the high current component to an adjacent contact pad by way of a thick metal interconnect layer.