A semiconductor device includes a semiconductor substrate, a power transistor formed in the semiconductor substrate, the power transistor including an active area in which one or more power transistor cells are formed, a first metal pad formed above the semiconductor substrate and covering substantially all of the active area of the power transistor, the first metal pad being electrically connected to a source or emitter region in the active area of the power transistor, the first metal pad including an interior region laterally surrounded by a peripheral region, the peripheral region being thicker than the interior region, and a first interconnect plate or a semiconductor die attached to the interior region of the first metal pad by a die attach material. Corresponding methods of manufacture are also described.

A connection terminal unit that can be appropriately connected to terminal connection portions of a semiconductor module including a semiconductor element and that can reduce a projection area when seen in a direction orthogonal to a direction along a chip surface is realized. Connection terminal unit includes plurality of connection terminals facing and connected to plurality of terminal connection portions of semiconductor module, and terminal mold portion holding connection terminals. Terminal mold portion has abutment portion that abuts against semiconductor module or base material holding semiconductor module. Abutment portion has vertical abutment portion that abuts against semiconductor module or base material from vertical direction that is a direction in which connection terminals face terminal connection portions, and side abutment portion that abuts against semiconductor module or base material from at least two directions that are different from each other and intersect with vertical direction.

A method includes forming a metal post over a first dielectric layer, attaching a second dielectric layer over the first dielectric layer, encapsulating a device die, the second dielectric layer, a shielding structure, and the metal post in an encapsulating material, planarizing the encapsulating material to reveal the device die, the shielding structure, and the metal post, and forming an antenna electrically coupling to the device die. The antenna has a portion vertically aligned to a portion of the device die.

A package and method of making a package is disclosed. In one example, the package includes an electronic chip having at least one pad, an encapsulant at least partially encapsulating the electronic chip, and an electrically conductive contact element extending from the at least one pad and through the encapsulant so as to be exposed with respect to the encapsulant. The electrically conductive contact element comprises a first contact structure made of a first electrically conductive material on the at least one pad and comprises a second contact structure made of a second electrically conductive material and being exposed with respect to the encapsulant. At least one of the at least one pad has at least a surface portion which comprises or is made of the first electrically conductive material.

A package structure includes a semiconductor die, a redistribution circuit structure, and a metallization element. The semiconductor die has an active side and an opposite side opposite to the active side. The redistribution circuit structure is disposed on the active side and is electrically coupled to the semiconductor die. The metallization element has a plate portion and a branch portion connecting to the plate portion, wherein the metallization element is electrically isolated to the semiconductor die, and the plate portion of the metallization element is in contact with the opposite side.

An embodiment of the present application discloses an optical fingerprint identification apparatus and an electronic device, which can improve performance of the optical fingerprint identification apparatus. The optical fingerprint identification apparatus includes: a light detection array; a filter layer, disposed above the light detection array, where the filter layer is integrated with the light detection array in a photosensor chip; a first light blocking layer formed above the filter layer, where the first light blocking layer is provided with a plurality of light passing holes; and a first microlens array disposed above the first light blocking layer, where the first microlens array is configured to converge the optical signal to the plurality of light passing holes of the first light blocking layer, and the optical signal is transmitted to the light detection array through the plurality of light passing holes of the first light blocking layer.

A semiconductor device includes a semiconductor substrate, a power transistor formed in the semiconductor substrate, the power transistor including an active area in which one or more power transistor cells are formed, a first metal pad formed above the semiconductor substrate and covering substantially all of the active area of the power transistor, the first metal pad being electrically connected to a source or emitter region in the active area of the power transistor, the first metal pad including an interior region laterally surrounded by a peripheral region, the peripheral region being thicker than the interior region, and a first interconnect plate or a semiconductor die attached to the interior region of the first metal pad by a die attach material. Corresponding methods of manufacture are also described.

A three dimensional integrated circuit (3D-IC) module socket system includes an integrated Fan-Out (InFO) adapter having one or more integrated passive devices (IPDs) embedded in the InFO adapter. The InFO adapter is also integrated into the 3D-IC module socket system by stacking the InFO adapter between a socket and a SoW package. The InFO adapter with embedded IPDs allows for more planar area of the SoW package to be available for interfacing the socket and provides a short distance between the embedded IPDs and computing dies of the SoW package which enhances a power distribution network (PDN) performance and improves current handling of the 3D-IC module socket system.

A package and method of making a package is disclosed. In one example, the package includes an electronic chip having at least one pad, an encapsulant at least partially encapsulating the electronic chip, and an electrically conductive contact element extending from the at least one pad and through the encapsulant so as to be exposed with respect to the encapsulant. The electrically conductive contact element comprises a first contact structure made of a first electrically conductive material on the at least one pad and comprises a second contact structure made of a second electrically conductive material and being exposed with respect to the encapsulant. At least one of the at least one pad has at least a surface portion which comprises or is made of the first electrically conductive material.

A method includes forming a metal post over a first dielectric layer, attaching a second dielectric layer over the first dielectric layer, encapsulating a device die, the second dielectric layer, a shielding structure, and the metal post in an encapsulating material, planarizing the encapsulating material to reveal the device die, the shielding structure, and the metal post, and forming an antenna electrically coupling to the device die. The antenna has a portion vertically aligned to a portion of the device die.