A method and apparatus for multiple flexible circuit cable attachment is described herein. Gold bumps are bonded on interconnection pads of a substrate to create a columnar structure and solder or conductive epoxy is dispensed on the flexible cable circuit. The substrate and flexible cable circuit are aligned and pressed together using force or placement of a weight on either the substrate or flexible cable circuit. Appropriate heat is applied to reflow the solder or cure the epoxy. The solder wets to the substrate pads, assisted by the gold bumps, and have reduced bridging risk due to the columnar structure. A nonconductive underfill epoxy is applied to increase mechanical strength.

A method for forming an integrated circuit (IC) package is provided. In some embodiments, a semiconductor workpiece comprising a scribe line, a first IC die, a second IC die, and a passivation layer is formed. The scribe line separates the first and second IC dies, and the passivation layer covers the first and second IC dies. The first IC die comprises a circuit and a pad structure electrically coupled to the circuit. The pad structure comprises a first pad, a second pad, and a bridge. The bridge is within the scribe line and connects the first pad to the second pad. The passivation layer is patterned to expose the first pad, but not the second pad, and testing is performed on the circuit through the first pad. The semiconductor workpiece is cut along the scribe line to individualize the first and second IC dies, and to remove the bridge.

A method and apparatus for multiple flexible circuit cable attachment is described herein. Gold bumps are bonded on interconnection pads of a substrate to create a columnar structure and solder or conductive epoxy is dispensed on the flexible cable circuit. The substrate and flexible cable circuit are aligned and pressed together using force or placement of a weight on either the substrate or flexible cable circuit. Appropriate heat is applied to reflow the solder or cure the epoxy. The solder wets to the substrate pads, assisted by the gold bumps, and have reduced bridging risk due to the columnar structure. A nonconductive underfill epoxy is applied to increase mechanical strength.

A method for forming an integrated circuit (IC) package is provided. In some embodiments, a semiconductor workpiece comprising a scribe line, a first IC die, a second IC die, and a passivation layer is formed. The scribe line separates the first and second IC dies, and the passivation layer covers the first and second IC dies. The first IC die comprises a circuit and a pad structure electrically coupled to the circuit. The pad structure comprises a first pad, a second pad, and a bridge. The bridge is within the scribe line and connects the first pad to the second pad. The passivation layer is patterned to expose the first pad, but not the second pad, and testing is performed on the circuit through the first pad. The semiconductor workpiece is cut along the scribe line to individualize the first and second IC dies, and to remove the bridge.

An ultrasonic transducer system is provided. The ultrasonic transducer system includes a transducer body, wherein at least a portion of a surface of the transducer body includes a processed area. The processed area has a changed condition at the surface of the transducer body.

Provided are a three-dimensional shaped object production device and method capable of producing a predetermined three-dimensional shaped object by forming a ball at a leading end of a conductive wire through use of the conductive wire based on scanned data or designed data and aligning and stacking the balls. The three-dimensional shaped object production device includes: a plate (40), on which a three-dimensional shaped object is placeable; a ball forming section configured to form a ball (13) by applying high voltage between a leading end of a conductive wire (4) paid out from a leading end of a capillary (12) and a spark rod (19) and melting the leading end of the wire by discharge energy; a positioning device configured to position the plate and the ball forming section by moving the plate and the ball forming section relative to each other; and a bonding section configured to bond the ball formed at the leading end of the capillary to another ball (14) that has already been stacked on the plate, the forming of the ball by the ball forming section, the relative moving of the plate and the ball forming section by the positioning device, and the bonding of the ball formed at the leading end of the capillary to the another ball by the bonding section is repeated, to thereby produce a three-dimensional shaped object having a desired shape.

A method and apparatus for multiple flexible circuit cable attachment is described herein. Gold bumps are bonded on interconnection pads of a substrate to create a columnar structure and solder or conductive epoxy is dispensed on the flexible cable circuit. The substrate and flexible cable circuit are aligned and pressed together using force or placement of a weight on either the substrate or flexible cable circuit. Appropriate heat is applied to reflow the solder or cure the epoxy. The solder wets to the substrate pads, assisted by the gold bumps, and have reduced bridging risk due to the columnar structure. A nonconductive underfill epoxy is applied to increase mechanical strength.

According to a first aspect of the present invention, there is provided a bond apparatus for bonding a wire to a bonding surface, comprising: a bond head body movably retained by a mounting portion; a first actuator; and a second actuator, wherein the bond head body has a tool portion configured to receive a bonding tool for receiving and bonding the wire and an actuator portion coupled with the first actuator and the second actuator, the first actuator and the second actuator being operative to act on the actuator portion for moving the bond head body with respect to the mounting portion to move the bonding tool with respect to the bonding surface.

A wire bonding method comprises: preparing a wire bonding apparatus; a step of forming a free air ball; a first height measuring step of measuring the height of a first electrode by detecting whether the free air ball is grounded to the first electrode; a second height measuring step of measuring the height of a second electrode by detecting whether the free air ball is grounded to the second electrode; a first bonding step of controlling the height of a bonding tool based on the measurement result in the first height measuring step, and bonding the free air ball to the first electrode; and a second bonding step of controlling the height of the bonding tool based on the measurement result in the second height measuring step, and bonding a wire to the second electrode to connect the first and the second electrodes. Thus, electrodes can be correctly bonded.

A method for forming an integrated circuit (IC) package is provided. In some embodiments, a semiconductor workpiece comprising a scribe line, a first IC die, a second IC die, and a passivation layer is formed. The scribe line separates the first and second IC dies, and the passivation layer covers the first and second IC dies. The first IC die comprises a circuit and a pad structure electrically coupled to the circuit. The pad structure comprises a first pad, a second pad, and a bridge. The bridge is within the scribe line and connects the first pad to the second pad. The passivation layer is patterned to expose the first pad, but not the second pad, and testing is performed on the circuit through the first pad. The semiconductor workpiece is cut along the scribe line to individualize the first and second IC dies, and to remove the bridge.