An electrical interconnection includes a wire loop having a first end bonded to a first bonding site using a first bonding portion, and a second end bonded to a second bonding site using a second bonding portion. The second bonding portion includes a folded portion having a wire that extends from the second end of the wire loop and is folded on the second bonding site. The folded portion includes a first folded portion connected to the second end of the wire loop and extending toward the first bonding site, a second folded portion provided on the first folded portion, and a tail protruding from a portion of the second folded portion. An interface is formed between the first and second folded portions. A top surface of the second folded portion includes an inclined surface recessed toward the first folded portion.

A manufacturing method for a wire bonding structure of the present invention includes a step of preparing a wire made of Cu and a step of joining the wire to a first joining target formed on an electronic device. Before the joining step, the wire has an outer circumferential surface and a withdrawn surface. The withdrawn surface is withdrawn toward a central axis of the wire from the outer circumferential surface. In the joining step, ultrasonic vibration is applied to the wire in a state in which the withdrawn surface is pressed against the first joining target.

Disclosed is a COB die bonding and wire bonding system and method. The system comprises a controller, a forward die bonder, a reverse die bonder and a conveyor belt, the controller being connected with the forward die bonder and the reverse die bonder respectively, and the forward die bonder is associated with the reverse die bonder by the conveyor belt. The system and method can realize the combination of the forward and reverse bonding when using the forward die bonder and the reverse die bonder to fix the chips, thus the amount of gold wire used for connecting chips on a substrate is minimized. The COB die bonding and wire bonding system and method can be widely used in the field of electronics.

A semiconductor device includes a die pad, a semiconductor chip with a bonding pad being formed, a lead one end of which is located in the vicinity of the semiconductor chip, a coupling wire that connects an electrode and the lead, and a sealing body that seals the semiconductor chip, the coupling wire, a part of the lead, and a part of the die pad. A lower surface of the die pad is exposed from a lower surface of the sealing body, the die pad and the coupling wire are comprised of copper, and a thickness of the semiconductor chip is larger than the sum of a thickness of the die pad and a thickness from an upper surface of the semiconductor chip to an upper surface of the sealing body.

A semiconductor device including a package substrate having, at the periphery of the main surface thereof, bonding leads disposed in a row, a semiconductor chip mounted inside of the row of the bonding leads on the main surface of the package substrate, wires for connecting pads of the semiconductor chip and the bonding leads of the substrate, a sealing body for resin sealing the semiconductor chip and the wires, and solder bumps disposed on the back surface of the package substrate. The top of a loop of each of the wires is disposed outside the wire connecting portion so that the wire connection between the bonding leads and the pads of the semiconductor chip has a stable loop shape to prevent wire connection failure.

A semiconductor device including a package substrate having, at the periphery of the main surface thereof, bonding leads disposed in a row, a semiconductor chip mounted inside of the row of the bonding leads on the main surface of the package substrate, wires for connecting pads of the semiconductor chip and the bonding leads of the substrate, a sealing body for resin sealing the semiconductor chip and the wires, and solder bumps disposed on the back surface of the package substrate. The top of a loop of each of the wires is disposed outside the wire connecting portion so that the wire connection between the bonding leads and the pads of the semiconductor chip has a stable loop shape to prevent wire connection failure.

In examples, a package comprises a semiconductor die having a device side and a bond pad on the device side, a conductive terminal exposed to an exterior of the package, and an electrical fuse. The electrical fuse comprises a conductive ball coupled to the bond pad, and a bond wire coupled to the conductive terminal. The bond wire is stitch-bonded to the conductive ball.

Semiconductor device packages include first and second semiconductor dice in a facing relationship. At least one group of solder bumps is substantially along a centerline between the semiconductor dice and operably coupled with integrated circuitry of the first and second semiconductor dice. Another group of solder bumps is laterally offset from the centerline and operably coupled only with integrated circuitry of the first semiconductor die. A further group of solder bumps is laterally offset from the centerline and operably coupled only with integrated circuitry of the second semiconductor die. Methods of forming semiconductor device packages include aligning first and second semiconductor dice with active surfaces facing each other, the first and second semiconductor dice each including bond pads along a centerline thereof and additional bond pads laterally offset from the centerline thereof.

Stacked microfeature devices and associated methods of manufacture are disclosed. A package in accordance with one embodiment includes first and second microfeature devices having corresponding first and second bond pad surfaces that face toward each other. First bond pads can be positioned at least proximate to the first bond pad surface and second bond pads can be positioned at least proximate to the second bond pad surface. A package connection site can provide electrical communication between the first microfeature device and components external to the package. A wirebond can be coupled between at least one of the first bond pads and the package connection site, and an electrically conductive link can be coupled between the first microfeature device and at least one of the second bond pads of the second microfeature device. Accordingly, the first microfeature device can form a portion of an electrical link to the second microfeature device.

Stacked microfeature devices and associated methods of manufacture are disclosed. A package in accordance with one embodiment includes first and second microfeature devices having corresponding first and second bond pad surfaces that face toward each other. First bond pads can be positioned at least proximate to the first bond pad surface and second bond pads can be positioned at least proximate to the second bond pad surface. A package connection site can provide electrical communication between the first microfeature device and components external to the package. A wirebond can be coupled between at least one of the first bond pads and the package connection site, and an electrically conductive link can be coupled between the first microfeature device and at least one of the second bond pads of the second microfeature device. Accordingly, the first microfeature device can form a portion of an electrical link to the second microfeature device.