A bonding apparatus includes a stage on which a substrate is seated, a gantry installed above the stage, a bonding unit configured to bond a chip to the substrate while moving along the gantry, and a control part moving the bonding unit to align the bonding unit with a bonding position on the substrate, controlling the bonding unit to allow the bonding unit to bond the chip at the bonding position, determining a movement distance of the bonding unit based on a weighted sum of a number of continuous operations and an idle time of the bonding unit.

According to an aspect, a manufacturing method of a display device includes: obtaining a first reference position on a surface of a holding substrate based on positions of a plurality of first alignment marks of the holding substrate; and aligning the holding substrate with a transfer destination substrate such that the first reference position on the holding substrate and a second reference position on a surface of the transfer destination substrate coincide. The holding substrate is sectioned into a plurality of first sections and a plurality of second sections when viewed from one direction. Each of the first sections is provided in a part of a gap between the second sections when viewed from the one direction, has a light transmission rate higher than a light transmission rate of the second sections, and forms the first alignment mark through which light passes when viewed from the one direction.

A hybridized image sensor includes a first die and a second die. The first die includes a first surface, a first plurality of conductive bumps fabricated on the first surface, and a first alignment feature fabricated on the first surface. The second die includes a second surface, a second plurality of conductive bumps fabricated on the second surface, and second alignment features fabricated on the second surface, wherein the first alignment features interact with the second alignment features to align the first plurality of conductive bumps with the second plurality of conductive bumps.

A bonding apparatus includes a stage on which a substrate is seated, a gantry installed above the stage, a bonding unit configured to bond a chip to the substrate while moving along the gantry, and a control part moving the bonding unit to align the bonding unit with a bonding position on the substrate, controlling the bonding unit to allow the bonding unit to bond the chip at the bonding position, determining a movement distance of the bonding unit based on a weighted sum of a number of continuous operations and an idle time of the bonding unit.

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 method of making a semiconductor device involves the steps of disposing a first semiconductor die over a substrate and disposing a beam homogenizer over the first semiconductor die. A beam from the beam homogenizer impacts the first semiconductor die. The method further includes the steps of determining a positional offset of the beam relative to the first semiconductor die in a number of pixels, using a first calibration equation to convert the number of pixels into a distance in millimeters, and moving the beam homogenizer the distance in millimeters to align the beam and first semiconductor die.

A hybridized image sensor includes a first die and a second die. The first die includes a first surface, a first plurality of conductive bumps fabricated on the first surface, and a first alignment feature fabricated on the first surface. The second die includes a second surface, a second plurality of conductive bumps fabricated on the second surface, and second alignment features fabricated on the second surface, wherein the first alignment features interact with the second alignment features to align the first plurality of conductive bumps with the second plurality of conductive bumps.

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 method of making a semiconductor device involves the steps of disposing a first semiconductor die over a substrate and disposing a beam homogenizer over the first semiconductor die. A beam from the beam homogenizer impacts the first semiconductor die. The method further includes the steps of determining a positional offset of the beam relative to the first semiconductor die in a number of pixels, using a first calibration equation to convert the number of pixels into a distance in millimeters, and moving the beam homogenizer the distance in millimeters to align the beam and first semiconductor die.

A flip-chip laser bonding apparatus and method are provided in which flip-chip type semiconductor chips are bonded to a substrate using laser light. The flip-chip laser bonding apparatus and method are effective in rapidly bonding bent or flexible flip-chip type semiconductor chips to a substrate with high quality without contact defects of solder bumps.