This mounting device (100) comprises: a base (10) that moves linearly in relation to a substrate (16); a bonding head (20) that is attached to the base (10); a camera (25) that is attached to the base (10) and identifies the position of the substrate (16); a linear scale (33) having a plurality of graduations along the movement direction; a bonding head-side encoder head (31); and a camera-side encoder head (32). A control unit (50) causes the base (10) to move to a position where the bonding head-side encoder head (31) detects the position of a graduation. Due to this configuration, positioning accuracy of a semiconductor die (15) in relation to the substrate (16) is improved.

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.

The present disclosure relates to a full-automatic deep access ball bonding head device includes: a Z-axis base; a Z-axis sliding stage, which is connected to the Z-axis base in a sliding manner along Z-axis; an EFO mechanism; and a bonding mechanism, which is fixed on the Z-axis sliding stage. The EFO mechanism includes an EFO sliding block, an EFO wand, and a compressed spring. The EFO sliding block is located on the side of the Z-axis sliding stage and connected to the Z-axis base in a sliding manner. The compressed spring is connected between the upper end of the Z-axis sliding stage and the upper end of the EFO sliding block, and the EFO wand is connected to the lower end of the EFO sliding block.

A height of a vertical wire interconnection bonded onto a substrate is measured by first capturing a top view of the vertical wire interconnection and identifying a position of a tip end of the vertical wire interconnection from the top view. A conductive probe is located over the tip end of the vertical wire interconnection, and is lowered towards the vertical wire interconnection until an electrical connection is made between the conductive probe and the tip end of the vertical wire interconnection. A contact height at which the electrical connection is made may thus be determined, wherein the contact height corresponds to the height of the vertical wire interconnection.

This mounting device (100) comprises: a base (10) that moves linearly in relation to a substrate (16); a bonding head (20) that is attached to the base (10); a camera (25) that is attached to the base (10) and identifies the position of the substrate (16); a linear scale (33) having a plurality of graduations along the movement direction; a bonding head-side encoder head (31); and a camera-side encoder head (32). A control unit (50) causes the base (10) to move to a position where the bonding head-side encoder head (31) detects the position of a graduation. Due to this configuration, positioning accuracy of a semiconductor die (15) in relation to the substrate (16) is improved.

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.

A method is provided for connecting a chip die to a circuit board with a capillary dispenser to deposit gold. The method includes forming a first bond by depositing gold from the dispenser to a board pad on the circuit board; forming a second bond by depositing the gold from the dispenser to a die pad on the chip die; extruding a filament of the gold by the dispenser in a normal direction from the second bond; rotating the filament laterally away from the first bond along a first radius; extruding the filament while rotating the filament towards the first bond along a second radius larger than the first radius; and forming a third bond by depositing the gold on the first bond to form a third bond.

A wire bonding method for connecting a wire to two different surfaces by bonding with a single wire bonding step. The wire bonding method includes: bonding one end of a wire fed from a distal end of a capillary to a first bonding surface; moving the capillary in the Z direction; moving the capillary the X and/or Y direction; moving the capillary in the X, Y, and/or Z direction, a plurality of times; moving the capillary to a highest position; and bonding another end of the wire to the second bonding surface. The wire bonding method includes, at any timing, rotating the first bonding surface about a rotation axis to move the second bonding surface to a position capable of bonding. An angle formed by the first bonding surface and the second bonding surface on a side where the wire is stretched is 200? or more.

A wire bonding apparatus connecting a lead of a mounted member with an electrode of a semiconductor die through a wire comprises a capillary through which the wire is inserted, a shape acquisition part which acquires the shape of the lead to which the wire is connected, a calculating part which calculates an extending direction of a wire tail extending from the end of the capillary based on the shape of a lead to which the wire is connected next, and a cutting part which moves the capillary in the extending direction and cuts the wire to form the wire tail after the lead is connected with the electrode through the wire. Thus, in the wire bonding using wedge bonding, joining part tails (183a, 283a, 383a) formed in continuation to a first bonding point can be prevented from coming into contact with each other.

The disclosure shows a mounting apparatus including a primary pedestal with a mounting stage installed thereon, a gantry frame supported on the primary pedestal, mounting heads supported on the gantry frame in a manner movable in the Y direction, a secondary pedestal arranged apart from the primary pedestal, and a Y-direction load receiver installed on the secondary pedestal in a manner movable in the X direction and immovable in the Y direction, in which an X-direction stator is attached to the secondary pedestal, and in which one end of a Y-direction stator attached to the gantry frame and the Y-direction load receiver are connected using a connection member, thereby suppressing vibration of the primary pedestal caused when the plurality of mounting heads are moved in the X and Y directions.