An electronic device includes a multilevel package substrate with first and second levels extending in planes of first and second directions and spaced apart from one another along a third direction, the first level having a first side with landing areas and the second level having a second side with conductive landing pads. The electronic device includes a die with conductive terminals electrically coupled to respective ones of the landing areas, as well as solder balls attached to respective ones of the landing pads, and a package structure that encloses the die and a portion of the multilevel package substrate.

An electronic device includes a multilevel package substrate with first and second levels extending in planes of first and second directions and spaced apart from one another along a third direction, the first level having a first side with landing areas and the second level having a second side with conductive landing pads. The electronic device includes a die with conductive terminals electrically coupled to respective ones of the landing areas, as well as solder balls attached to respective ones of the landing pads, and a package structure that encloses the die and a portion of the multilevel package substrate.

A semiconductor device according to one embodiment includes: a semiconductor chip having a transistor and a drain pad provided on a board; a capacitor having an upper electrode and a lower electrode interposing a dielectric; a pad; and an empty pad provided on the board of the semiconductor chip. The semiconductor device further includes: a first wire connecting the pad and the drain pad of the semiconductor chip to each other; a second wire connecting the empty pad and the upper electrode of the capacitor to each other; and a third wire connecting the pad and the empty pad to each other.

A wire bonding device for performing a wire bonding process includes: a bonding tool for inserting a wire; an ultrasonic vibrator; a drive mechanism for moving the bonding tool; and a control part. The control part performs: a bonding step of bonding the wire to a bonding point; a tail feeding out step of feeding out a wire tail from the wire bonded to the bonding point; a tension applying step of raising the bonding tool to apply tension to the wire while the wire is clamped; a tension release step of lowering the bonding tool to release the tension applied to the wire; and after performing a series of steps including the tension applying step and the tension release step at least once, a tail cutting step of raising the bonding tool to cut the wire tail from the wire.

A method for forming a chip package structure is provided. The method includes removing a first portion of a substrate to form a first recess in the substrate. The method includes forming a buffer structure in the first recess. A first Young's modulus of the buffer structure is less than a second Young's modulus of the substrate. The method includes forming a first wiring structure over the buffer structure and the substrate. The method includes bonding a chip package to the first wiring structure. The chip package has an interposer substrate and a chip structure over the interposer substrate, and a first corner of the interposer substrate and a second corner of the chip structure overlap the buffer structure in a top view of the chip package and the buffer structure.

A method for forming a chip package structure is provided. The method includes removing a first portion of a substrate to form a first recess in the substrate. The method includes forming a buffer structure in the first recess. A first Young's modulus of the buffer structure is less than a second Young's modulus of the substrate. The method includes forming a first wiring structure over the buffer structure and the substrate. The method includes bonding a chip package to the first wiring structure. The chip package has an interposer substrate and a chip structure over the interposer substrate, and a first corner of the interposer substrate and a second corner of the chip structure overlap the buffer structure in a top view of the chip package and the buffer structure.

A method of using a solder reflow oven can include disposing at least one substrate including solder in a chamber of the oven. The method can include decreasing a pressure of the chamber to a first pressure between about 0.1-50 Torr. After decreasing the pressure of the chamber, the temperature of the at least one substrate can be increased to a first temperature. Formic acid vapor can be admitted into the chamber above the at least one substrate while nitrogen is discharged into the chamber below the at least one substrate. The method can also include removing at least a portion of the formic acid vapor from the enclosure. After the removing step, the temperature of the at least one substrate can be further increased to a second temperature higher than the first temperature. The at least one substrate can be maintained at the second temperature for a first time. And then, the at least one substrate can be cooled.

A light detection and ranging (LIDAR) system and apparatus including a photonics chip mounted to a substrate, the photonics chip including one or more optical components and one or more electrical components and one or more integrated circuit (IC) chips mounted to the photonics chip to process an electrical signal generated by the one or more optical components and the one or more electrical components, wherein the one or more IC chips are physically separated from the substrate to reduce crosstalk on the LIDAR apparatus.

A light detection and ranging (LIDAR) system and apparatus including a photonics chip mounted to a substrate, the photonics chip including one or more optical components and one or more electrical components and one or more integrated circuit (IC) chips mounted to the photonics chip to process an electrical signal generated by the one or more optical components and the one or more electrical components, wherein the one or more IC chips are physically separated from the substrate to reduce crosstalk on the LIDAR apparatus.

An electronic device includes a substrate having contact pads disposed thereon and traces interconnecting the contact pads. A first integrated circuit (IC) die is mounted on the substrate and includes a predefined set of circuit components arranged on the first IC die in a first geometrical pattern, which is non-symmetrical under reflection about a given axis in a plane of the die. A second IC die is mounted on the substrate and includes the predefined set of circuit components arranged on the second IC die in a second geometrical pattern, which is a mirror image of the first geometrical pattern with respect to the given axis.