A multi-clip structure includes a first clip for die bonding and a second clip for die bonding. The multi-clip structure further includes a retaining tape fixed to the first clip and to the second clip to hold the first clip and the second clip together.

A fingerprint sensor package includes: a first substrate including a core insulating layer including a first surface and a second surface and a through-hole, a first bonding pad on the second surface, and an external connection pad between an edge of the second surface and the first bonding pad; a second substrate in the through-hole and including a third surface and a fourth surface, and including first sensing patterns on the third surface, spaced apart in a first direction, and extending in a second direction, second sensing patterns spaced apart from each other in the second direction and extending in the first direction, and a second bonding pad on the fourth surface; a conductive support electrically connecting the first bonding pad and the second bonding pad and supporting the first substrate and the second substrate; a controller chip on the second substrate; and a molding layer on the second surface.

An electronic device made from the method of providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, laser bending the shaped metallic interconnects; and transferring the shaped metallic interconnects onto a receiving substrate or device.

An apparatus includes a circuit substrate including a circuit trace and a micro-sized semiconductor device die electrically connected to the circuit substrate. The micro-sized semiconductor device die has a height not greater than 400 microns and a width not greater than 800 microns. An anisotropic conductive adhesive (ACA) is disposed between the circuit substrate and the micro-sized semiconductor device die, thereby providing an electrical connection from the circuit substrate to the micro-sized semiconductor device die.

An electronic device made from the method of providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, laser bending the shaped metallic interconnects; and transferring the shaped metallic interconnects onto a receiving substrate or device.

A method of forming and transferring shaped metallic interconnects, comprising providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, and transferring the shaped metallic interconnect to an electrical device. An electronic device made from the method of providing a donor ribbon, wherein the donor ribbon comprises an array of metal structures and a release layer on a donor substrate, providing a stencil to the metal structures on the donor substrate, applying a laser pulse through the donor substrate to the metal structures, and directing the metal structures to an electronic device.

A clip tape includes connected clip sets; each includes a first clip and a second clip oriented in a same direction, connected by a connector bar. A first multi-chip module and a second multi-chip module are formed by providing a lead frame array containing lead frame units, and providing a clip tape containing connected clip sets. A connected clip set is separated from the clip tape as a unit and placed on the lead frame array; the first clip in the first multi-chip module, and the second clip in the second multi-chip module. The connector bar remains attached during a heating operation, and is severed by a singulation process. A multi-chip module includes a lead frame unit, a semiconductor device, and a clip of a connected clip set attached to the semiconductor device. A connector bar extends from the clip to an external surface of the multi-chip module.

A method of forming and transferring shaped metallic interconnects, comprising providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, and transferring the shaped metallic interconnect to an electrical device. An electronic device made from the method of providing a donor ribbon, wherein the donor ribbon comprises an array of metal structures and a release layer on a donor substrate, providing a stencil to the metal structures on the donor substrate, applying a laser pulse through the donor substrate to the metal structures, and directing the metal structures to an electronic device.

A method of forming and transferring shaped metallic interconnects, comprising providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, and transferring the shaped metallic interconnect to an electrical device. An electronic device made from the method of providing a donor ribbon, wherein the donor ribbon comprises an array of metal structures and a release layer on a donor substrate, providing a stencil to the metal structures on the donor substrate, applying a laser pulse through the donor substrate to the metal structures, and directing the metal structures to an electronic device.

A method of forming and transferring shaped metallic interconnects, comprising providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, and transferring the shaped metallic interconnect to an electrical device. An electronic device made from the method of providing a donor ribbon, wherein the donor ribbon comprises an array of metal structures and a release layer on a donor substrate, providing a stencil to the metal structures on the donor substrate, applying a laser pulse through the donor substrate to the metal structures, and directing the metal structures to an electronic device.