Provided is a bonding apparatus including a bonding stage 83 for heating a substrate (lead frame) 61 placed on the upper surface thereof or a semiconductor die 63 mounted on the substrate (lead frame) 61, an imaging device 20 arranged above the bonding stage 83 to image the substrate 61 placed on the bonding stage 83 or the semiconductor die 63 mounted on the substrate 61, and a standing wave generating device 35 for generating an ultrasonic standing wave in the space between the upper surface of the bonding stage 83 and the imaging device 20. This improves the accuracy of image position detection by the imaging device with a simple structure.

A bonding apparatus includes: a clamper able to clamp a wire between a pair of arms; a horn, in which a first through hole able to hold a capillary, and a second through hole adjacent to the first through hole and penetrating the horn in an up-down direction are further formed; and a bonding stage able to carry a workpiece. An alignment method for aligning a horn and a damper of a bonding apparatus with each other includes: disposing a mirror surface to be parallel to a bonding stage; aligning a mirror image of a second through hole reflected on the mirror surface with a center of the second through hole when the mirror surface is viewed through the second through hole; and aligning the damper based on a position of the mirror image and the horn.

A bonding apparatus includes a bonding tool, first and second imaging units, a calculation part, and a drive control part. The first and second imaging units each include an optical system and an imaging element arranged to satisfy a Scheimpflug condition such that a plane parallel to a stage surface becomes a focal plane. The calculation part calculates three-dimensional coordinates of a target point to which a bonding wire is to be supplied next among bonding points, based on a first picture which is a picture of the target point captured in a first image outputted by the first imaging unit, and a second picture which is a picture of the target point captured in a second image outputted by the second imaging unit. The drive control part causes the bonding tool to approach the target point based on the three-dimensional coordinates of the target point.

In order to easily and accurately measure an offset for wire bonding and improve precision of wire bonding, a wiring bonding apparatus includes a first imaging unit, a bonding tool, a moving mechanism, a reference member, a second imaging unit arranged on the opposite side to the bonding tool and the first imaging unit with respect to a reference surface, and a control unit. The first imaging unit detects a position of an optical axis of the first image capture unit with respect to a position of the reference member, the second imaging unit detects the position of the reference member when moving the bonding tool above the reference member according to pre-stored offset values, and detects a position of a ball-shaped tip section of a wire, and the control unit measures a change in offset between the bonding tool and the first imaging unit based on each detection result.

In order to easily and accurately measure an offset for wire bonding and improve precision of wire bonding, a wiring bonding apparatus includes a first imaging unit, a bonding tool, a moving mechanism, a reference member, a second imaging unit arranged on the opposite side to the bonding tool and the first imaging unit with respect to a reference surface, and a control unit. The first imaging unit detects a position of an optical axis of the first image capture unit with respect to a position of the reference member, the second imaging unit detects the position of the reference member when moving the bonding tool above the reference member according to pre-stored offset values, and detects a position of a ball-shaped tip section of a wire, and the control unit measures a change in offset between the bonding tool and the first imaging unit based on each detection result.

A bonding apparatus 10 having a diagonal optical system 30, the bonding apparatus moves a capillary 24 down to a first heightwise position to calculate a position A11 of a tip end portion of the capillary 24 and a position A12 of a tip end portion of the capillary in an image on an imaging plane of the diagonal optical system 30, and similarly moves the capillary 24 down to a further lower second heightwise position to calculate a position A21 of the tip end portion of the capillary 24 and a position A22 of the tip end portion of the capillary in the image on the imaging plane. The bonding apparatus then estimates the position of the landing point of the capillary 24 on a bonding target 8 based on positional data for the four calculated positions A11, A12, A21, and A22, the first heightwise position, and the second heightwise position. With this, it is possible to use the diagonal optical system in the bonding apparatus to further improve positional accuracy in the bonding process.

A wire bonding apparatus is provided with: a bonding stage on which a semiconductor chip is mounted; a wire bonding unit including a capillary bonding a bonding wire to the semiconductor chip, a Z-axis drive section reciprocating the capillary, and a tool XY-stage causing the capillary and the Z-axis drive section to be moved along a two-dimensional plane intersecting a direction of reciprocation; and a base having an optical system and an optical system XY-stage causing the optical system to be moved along a two-dimensional plane intersecting a direction of reciprocation, the base having the wire bonding unit attached thereto. The wire bonding unit is attached to a first portion of the base, and the optical system XY-stage is attached to a second portion of the base which is separate from the first portion.

A mechanism is provided for identifying a wire-pull test location on a wire of a microelectronic package. A first distance between a first terminating location of the wire on the microelectronic package and a second terminating location of the wire on the microelectronic package is determined. Based on the first distance, a second distance from either the first terminating location or the second terminating location is determined as the wire-pull test location for testing a strength of a connection of the wire to at least one of the first terminating location or the second terminating location. An adjustment is performed such that a visual guide is oriented on the wire at the wire-pull test location.

A wire bonding apparatus includes: a capillary, performing predetermined processing on a workpiece and movable with respect to the workpiece; an optical mechanism, moving together with the capillary; and a controller. The optical mechanism includes: a first imaging unit, acquiring a first image obtained by imaging a standard point set within an imaging range; and a second imaging unit, acquiring a second image obtained by imaging a reference point formed at a predetermined distance from the capillary. The controller positions the capillary with respect to the workpiece based on the first image, and calculates a positioning correction amount of the capillary based on the second image.