A package substrate and a semiconductor package including the same are provided. The semiconductor package includes a package substrate including a base having a front side and a back side, rear pads below the back side of the base, lower connection patterns below the rear pads and in contact with the rear pads, first and second front pads on the front side of the base, a first support pattern on the front side of the base having a thickness greater than a thickness of each of the first and second front pads, and a protective insulating layer on the front side of the base and having openings exposing the first and second front pads respectively, and on an upper surface and a side surface of the first support pattern; a lower semiconductor chip on the protective insulating layer of the package substrate, spaced apart from the first support pattern in a horizontal direction; and a first upper semiconductor chip on the package substrate vertically overlapping the lower semiconductor chip and the first support pattern.

A semiconductor package includes; a redistribution wiring layer, a controller chip centrally disposed on the redistribution wiring layer, a first sealant disposed on the redistribution wiring layer, wherein the controller chip is buried in the first sealant, through vias connected to the redistribution wiring layer through the first sealant, and a sub-package disposed on an upper surface of the first sealant. The sub-package may include a first stack structure disposed to one side of the controller chip on the upper surface of the first sealant and including vertically stacked chips, a second stack structure disposed to another side of the controller chip on the upper surface of the first sealant adjacent to the first stack structure in a first horizontal direction and including vertically stacked chips, and a second sealant sealing the first stack structure and the second stack structure.

An electronic package is provided, where a laterally diffused metal oxide semiconductor (LDMOS) type electronic structure is mounted onto a complementary metal oxide semiconductor (CMOS) type electronic element to be integrated into a chip module, thereby shortening electrical transmission path between the electronic structure and the electronic element so as to reduce the communication time between the electronic structure and the electronic element.

A method for fabricating semiconductor device includes the steps of first providing a first substrate having a high-voltage (HV) region and a medium voltage (MV) region and a second substrate having a low-voltage (LV) region and a static random access memory (SRAM) region, in which the HV region includes a HV device, the MV region includes a MV device, the LV region includes a fin field-effect transistor (FinFET), and the SRAM region includes a SRAM device. Next, a bonding process is conducted by using hybrid bonding, through-silicon interposer (TSI) or redistribution layer (RDL) for bonding the first substrate and the second substrate.

A semiconductor package includes a lower redistribution wiring layer; and a first semiconductor device on the lower redistribution wiring layer, the first semiconductor device being connected to the lower redistribution wiring layer via conductive bumps, wherein the lower redistribution wiring layer includes: a first redistribution wire in a first lower insulating layer; an insulating structure layer having an opening that exposes a portion of the first redistribution wire, the insulating structure layer including a first photosensitive insulating layer, a light blocking layer on the first photosensitive insulating layer, and a second photosensitive insulating layer on the light blocking layer; a second redistribution wire in the opening of the insulating structure layer, the second redistribution wire including a redistribution via contacting the first redistribution wire, and a redistribution line stacked on the redistribution via; and bonding pads bonded to the conductive bumps and electrically connected to the second redistribution wire.

Embodiments are generally directed to package stacking using chip to wafer bonding. An embodiment of a device includes a first stacked layer including one or more semiconductor dies, components or both, the first stacked layer further including a first dielectric layer, the first stacked layer being thinned to a first thickness; and a second stacked layer of one or more semiconductor dies, components, or both, the second stacked layer further including a second dielectric layer, the second stacked layer being fabricated on the first stacked layer.

Systems and methods for measuring and predicting the strength of semiconductor devices and packaging are disclosed. In some embodiments, a semiconductor device assembly comprises a package substrate, a semiconductor die electrically coupled to the package substrate, and a molding covering at least a portion of the semiconductor die, where the molding includes a through-mold via (TMV) extending from an upper surface into the mold material to a depth. The semiconductor device assembly can include a strain gauge disposed in the molding at the depth of the TMV and be electrically coupled to the TMV. For example, the TMV can extend to the surface of the semiconductor die, to the package substrate, or other critical areas of the semiconductor device assembly, enabling strain to be measured at these depths. The semiconductor device assembly can be used in testing to predict the strength of the die and packaging in real-world scenarios, such as being dropped, bent, or crushed.

A bonded structure is disclosed. The bonded structure can include a substrate. The bonded structure can include a first memory unit disposed on the substrate. The first memory unit can have a first stack of memory dies and a first logic controller disposed on the first stack. The first logic controller can manage data communicated to or from the first stack of memory dies. The bonded structure can also include a processor die hybrid bonded to the first memory unit along a bonding interface and a vertical interconnect connecting the substrate to the processor die. The bonded structure can further include a second memory unit disposed on the substrate. The second memory unit can include a second stack of memory dies and a second logic controller disposed on the second stack. The second logic controller can manage data communicated to or from the second stack of memory dies.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first die and a through-dielectric via (TDV) surrounded by a dielectric material in a first layer, where the TDV has a greater width at a first surface and a smaller width at an opposing second surface of the first layer; a second die, surrounded by the dielectric material, in a second layer on the first layer, where the first die is coupled to the second die by interconnects having a pitch of less than 10 microns, and the dielectric material around the second die has an interface seam extending from a second surface of the second layer towards an opposing first surface of the second layer with an angle of less than 90 degrees relative to the second surface; and a substrate on and coupled to the second layer.

This application is directed to packaging technology for providing an electronic device (e.g., a memory device). A memory device includes a stack of memory chips, a device substrate, and a conductive wire. The stack of memory chips includes a first memory chip having a chip pad that is formed on a surface of the first memory chip. The device substrate includes a plurality of substrate pads formed on a front surface of the device substrate. The front surface has a front opening, and the device substrate receives the stack of memory chips via the front opening of the front surface. The conductive wire is coupled to the front surface and the stack of memory chips, and is configure to couple the chip pad and one of the substrate pads electrically. In some embodiments, the device substrate includes a cutout opening that goes through an entire thickness of the device substrate.