In some embodiments, the present disclosure relates to an integrated chip (IC), including a substrate, a first die disposed over the substrate, a metal wire attached to a frontside of the first die, and a first plurality of die stopper bumps disposed along a backside of the first die and configured to control an angle of operation of the first die. The first plurality of die stopper bumps directly contacts a backside surface of the first die.

In some embodiments, the present disclosure relates to an integrated chip (IC), including a substrate, a first die disposed over the substrate, a metal wire attached to a frontside of the first die, and a first plurality of die stopper bumps disposed along a backside of the first die and configured to control an angle of operation of the first die. The first plurality of die stopper bumps directly contacts a backside surface of the first die.

Leadless power amplifier (PA) packages and methods for fabricating leadless PA packages having topside terminations are disclosed. In embodiments, the method includes providing electrically-conductive pillar supports and a base flange. At least a first radio frequency (RF) power die is attached to a die mount surface of the base flange and electrically interconnected with the pillar supports. Pillar contacts are further provided, with the pillar contacts electrically coupled to the pillar supports and projecting therefrom in a package height direction. The first RF power die is enclosed in a package body, which at least partially defines a package topside surface opposite a lower surface of the base flange. Topside input/out terminals are formed, which are accessible from the package topside surface and which are electrically interconnected with the first RF power die through the pillar contacts and the pillar supports.

Leadless power amplifier (PA) packages and methods for fabricating leadless PA packages having topside terminations are disclosed. In embodiments, the method includes providing electrically-conductive pillar supports and a base flange. At least a first radio frequency (RF) power die is attached to a die mount surface of the base flange and electrically interconnected with the pillar supports. Pillar contacts are further provided, with the pillar contacts electrically coupled to the pillar supports and projecting therefrom in a package height direction. The first RF power die is enclosed in a package body, which at least partially defines a package topside surface opposite a lower surface of the base flange. Topside input/out terminals are formed, which are accessible from the package topside surface and which are electrically interconnected with the first RF power die through the pillar contacts and the pillar supports.

Cryogenic integrated circuits are provided. A cryogenic integrated circuit includes a thermally conductive base, a data processer, a storage device, a buffer device, a thermally conductive shield and a cooling pipe. The data processer is located on the thermally conductive base. The storage device is located on the thermally conductive base and disposed aside and electrically connected to the data processer. The buffer device is disposed on the data processer. The thermally conductive shield covers the data processer, the storage device and the buffer device. The cooling pipe is located in physical contact with the thermally conductive base and disposed at least corresponding to the data processer.

Cryogenic integrated circuits are provided. A cryogenic integrated circuit includes a thermally conductive base, a data processer, a storage device, a buffer device, a thermally conductive shield and a cooling pipe. The data processer is located on the thermally conductive base. The storage device is located on the thermally conductive base and disposed aside and electrically connected to the data processer. The buffer device is disposed on the data processer. The thermally conductive shield covers the data processer, the storage device and the buffer device. The cooling pipe is located in physical contact with the thermally conductive base and disposed at least corresponding to the data processer.

In a described example, a method includes: forming a metal layer on a backside surface of a semiconductor wafer, the semiconductor wafer having semiconductor dies spaced apart by scribe lanes on an active surface of the semiconductor wafer opposite the backside surface; forming a layer with a modulus greater than about 4000 MPa up to about 8000 MPa over the metal layer; mounting the backside of the semiconductor wafer on a first side of a dicing tape having an adhesive; cutting through the semiconductor wafer, the metal layer, and the layer with a modulus greater than about 4000 MPa up to about 8000 MPa along scribe lanes; separating the semiconductor dies from the semiconductor wafer and from one another by stretching the dicing tape, expanding the cuts in the semiconductor wafer along the scribe lanes between the semiconductor dies; and removing the separated semiconductor dies from the dicing tape.

In a described example, a method includes: forming a metal layer on a backside surface of a semiconductor wafer, the semiconductor wafer having semiconductor dies spaced apart by scribe lanes on an active surface of the semiconductor wafer opposite the backside surface; forming a layer with a modulus greater than about 4000 MPa up to about 8000 MPa over the metal layer; mounting the backside of the semiconductor wafer on a first side of a dicing tape having an adhesive; cutting through the semiconductor wafer, the metal layer, and the layer with a modulus greater than about 4000 MPa up to about 8000 MPa along scribe lanes; separating the semiconductor dies from the semiconductor wafer and from one another by stretching the dicing tape, expanding the cuts in the semiconductor wafer along the scribe lanes between the semiconductor dies; and removing the separated semiconductor dies from the dicing tape.

A sensor package structure and a sensing module thereof are provided. The sensor package structure includes a substrate, a sensor chip disposed on the substrate, a light-curing layer disposed on the sensor chip, a light-permeable layer arranged above the sensor chip through the light-curing layer, and a shielding layer disposed on a surface of the light-permeable layer. The light-curing layer has an inner lateral side and an outer lateral side opposite to the inner lateral side, and the inner lateral side is separated from the outer lateral side by a first distance. In a transverse direction parallel to a top surface of the sensor chip, the outer lateral side is separated from an outer lateral edge by a second distance which is within a range of ½ to ⅓ of the first distance.

A sensor package structure and a sensing module thereof are provided. The sensor package structure includes a substrate, a sensor chip disposed on the substrate, a light-curing layer disposed on the sensor chip, a light-permeable layer arranged above the sensor chip through the light-curing layer, and a shielding layer disposed on a surface of the light-permeable layer. The light-curing layer has an inner lateral side and an outer lateral side opposite to the inner lateral side, and the inner lateral side is separated from the outer lateral side by a first distance. In a transverse direction parallel to a top surface of the sensor chip, the outer lateral side is separated from an outer lateral edge by a second distance which is within a range of ½ to ⅓ of the first distance.