The present disclosure provides a package structure, including a mounting pad having a mounting surface, a semiconductor chip disposed on the mounting surface of the mounting pad, wherein the semiconductor chip includes a first surface, a second surface opposite to the first surface and facing the mounting surface, and a third surface connecting the first surface and the second surface, a first magnetic field shielding, including a first portion proximal to the third surface of the semiconductor chip, wherein the first portion has a first height calculated from the mounting surface to a top surface, and a second portion distal to the semiconductor chip, has a second height calculated from the mounting surface to a position at a surface facing away from the mounting surface, wherein the second height is less than the first height, wherein the second portion has an inclined sidewall.

A method for manufacturing a semiconductor device includes (i) a step of preparing a first semiconductor chip having a first electrode pad thereon and a second semiconductor chip having a second electrode pad thereon and larger in thickness than the first semiconductor chip, the second electrode pad being larger in size than the first electrode pad, (ii) a step of mounting the first semiconductor chip and the second semiconductor chip on the same planarized surface of a substrate having a uniform thickness, (iii) a step of bonding a ball formed by heating and melting a bonding wire to the second electrode pad, (iv) a step of first-bonding the bonding wire to the first electrode pad, and (v) a step of second-bonding the bonding wire to the ball.

The present disclosure provides a package structure, including a mounting pad having a mounting surface, a semiconductor chip disposed on the mounting surface of the mounting pad, wherein the semiconductor chip includes: a first surface perpendicular to a thickness direction of the semiconductor chip, a second surface opposite to the first surface and facing the mounting surface, and a third surface connecting the first surface and the second surface, a magnetic device disposed in the semiconductor chip, a first magnetic field shielding at least partially surrounding the third surface, a second magnetic field shielding, including a top surface facing the second surface of the semiconductor chip, and a molding surrounding the semiconductor chip, wherein the entire top surface of the second magnetic field shielding is in direct contact with the molding.

A method of determining a shear strength of a bonded free air ball on a wire bonding machine is provided. The method includes the steps of: (a) providing a free air ball at a working end of a wire bonding tool; (b) bonding the free air ball to a bonding location of a workpiece; (c) moving the wire bonding tool, while in contact with the bonded free air ball, in a direction along the bonding location; (d) monitoring wire bonding process signals during step (c); and (e) determining a shear strength using the wire bonding process signals monitored in step (d).

A chip package structure and an electronic equipment may reduce probability of short circuit failure during chip packaging and improve chip reliability. The chip package structure includes: a chip, a substrate, and a lead; the chip is disposed above the substrate; wherein the chip includes a pin pad and a test metal key, and the lead is configured to electrically connect the pin pad and the substrate; the test metal key is disposed in an edge region of the chip that is not under the lead.

A semiconductor device includes a single lead frame, a semiconductor element, and a mold material. The semiconductor element is joined onto one main surface of the lead frame. The lead frame includes a die-attach portion, a signal terminal portion, and a ground terminal portion. The die-attach portion, the signal terminal portion, and the ground terminal portion are disposed directly below the mold material so as to be arranged in a direction along one main surface. A groove portion is provided by partially removing the lead frame so as to allow the groove portion to pass therethrough, the groove portion being provided between the die-attach portion and the ground terminal portion adjacent to each other in the lead frame and between the signal terminal portion and the ground terminal portion adjacent to each other in the lead frame.

A bonding wire for connecting a first pad to a second pad is provided. The bonding wire includes a ball part bonded to the first pad, a neck part formed on the ball part, and a wire part extending from the neck part to the second pad. Less than an entire portion of a top surface of the neck part is covered by the wire part, and the wire part is in contact with the neck part, the ball part, and the first pad.

In a described example, an apparatus includes: a package substrate having a die mount portion and lead portions spaced from the die mount portion; a semiconductor die over the die mount portion having bond pads on an active surface facing away from the package substrate; non-gold bond wires forming electrical connections between at least one of the bond pads and one of the lead portions of the package substrate; a bond stitch on bump connection formed between one of the non-gold bond wires and a bond pad of the semiconductor die, comprising a stitch bond formed on a flex stud bump; and dielectric material covering a portion of the package substrate, the semiconductor die, the non-gold bond wires, the stitch bond and the flex stud bump, forming a packaged semiconductor device.

A capillary for performing ball bonding includes a body defining a lumen, a first blade defined in a lower tip of the body, and a second blade defined in the lower tip of the body for increasing reliability of a ball bonding procedure performed using the capillary.

A noble metal-coated silver bonding wire suppresses corrosion at the bonding interface under severe conditions of high temperature and high humidity, and the noble metal-coated silver bonding wire can be ball-bonded in the air. The noble metal-coated silver wire for ball bonding is a noble metal-coated silver wire including a noble metal coating layer on a core material made of pure silver or a silver alloy, wherein the wire contains at least one sulfur group element, the noble metal coating layer includes a palladium intermediate layer and a gold skin layer, the palladium content relative to the entire wire is 0.01 mass % or more and 5.0 mass % or less, the gold content relative to the entire wire is 1.0 mass % or more and 6.0 mass % or less, and the sulfur group element content relative to the entire wire is 0.1 mass ppm or more and 100 mass ppm or less.