A fingerprint sensor package includes: a first substrate including a core insulating layer including a first surface and a second surface and a through-hole, a first bonding pad on the second surface, and an external connection pad between an edge of the second surface and the first bonding pad; a second substrate in the through-hole and including a third surface and a fourth surface, and including first sensing patterns on the third surface, spaced apart in a first direction, and extending in a second direction, second sensing patterns spaced apart from each other in the second direction and extending in the first direction, and a second bonding pad on the fourth surface; a conductive support electrically connecting the first bonding pad and the second bonding pad and supporting the first substrate and the second substrate; a controller chip on the second substrate; and a molding layer on the second surface.

An exemplary semiconductor device can comprise a die, a redistribution structure (RDS), an interconnect, a conductive strap, an encapsulant, and an EMI shield. The redistribution structure can comprise an RDS top surface coupled to the die bottom side. The interconnect can be coupled to the RDS bottom surface. The conductive strap can be coupled to the RDS, and can comprise a strap inner end coupled to the RDS bottom surface, and a strap outer end located lower than the RDS bottom surface. The encapsulant can encapsulate the conductive strap and the RDS bottom surface. The EMI shield can cover and contact the encapsulant sidewall and the strap outer end. Other examples and related methods are also disclosed herein.

An electronic module has a first substrate 11, an electronic element 13, 23 disposed on one side of the first substrate 11, a second substrate 21 disposed on one side of the electronic element 13, 23, a first coupling body 210 disposed between the first substrate 11 and the second substrate 21, a second coupling body 220 disposed between the first substrate 11 and the second substrate 21, and shorter than the first coupling body 210, and a sealing part 90 which seals at least the electronic element. The first coupling body 210 is not electrically connected to the electronic element. The second coupling body 220 is electrically connected to the electronic element 13, 23.

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.

An exemplary semiconductor device can comprise a die, a redistribution structure (RDS), an interconnect, a conductive strap, an encapsulant, and an EMI shield. The redistribution structure can comprise an RDS top surface coupled to the die bottom side. The interconnect can be coupled to the RDS bottom surface. The conductive strap can be coupled to the RDS, and can comprise a strap inner end coupled to the RDS bottom surface, and a strap outer end located lower than the RDS bottom surface. The encapsulant can encapsulate the conductive strap and the RDS bottom surface. The EMI shield can cover and contact the encapsulant sidewall and the strap outer end. Other examples and related methods are also disclosed herein.

An exemplary semiconductor device can comprise a die, a redistribution structure (RDS), an interconnect, a conductive strap, an encapsulant, and an EMI shield. The redistribution structure can comprise an RDS top surface coupled to the die bottom side. The interconnect can be coupled to the RDS bottom surface. The conductive strap can be coupled to the RDS, and can comprise a strap inner end coupled to the RDS bottom surface, and a strap outer end located lower than the RDS bottom surface. The encapsulant can encapsulate the conductive strap and the RDS bottom surface. The EMI shield can cover and contact the encapsulant sidewall and the strap outer end. Other examples and related methods are also disclosed herein.

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 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 exemplary semiconductor device can comprise a die, a redistribution structure (RDS), an interconnect, a conductive strap, an encapsulant, and an EMI shield. The redistribution structure can comprise an RDS top surface coupled to the die bottom side. The interconnect can be coupled to the RDS bottom surface. The conductive strap can be coupled to the RDS, and can comprise a strap inner end coupled to the RDS bottom surface, and a strap outer end located lower than the RDS bottom surface. The encapsulant can encapsulate the conductive strap and the RDS bottom surface. The EMI shield can cover and contact the encapsulant sidewall and the strap outer end. Other examples and related methods are also disclosed herein.

This disclosure describes a power semiconductor module with at least one controlled power semiconductor bare die on an isolation substrate. The power semiconductor bare die includes a gate and a return control connection associated with pins that extend perpendicularly from the top of the power semiconductor bare die. One or more power terminals are connected to the isolation substrate.