Abstract: A method of depositing encapsulant on a line of wire bonds to a die is described, the die having a back surface in contact with the support structure and an active surface opposing the back surface, the active surface having electrical contact pads and functional elements spaced from the contact pads. The method involves the steps of providing a die mounted to the support structure, positioning a barrier between the contact pads and the functional elements, the barrier being proximate to, but spaced from the active surface, depositing a bead of encapsulant onto the electrical contact pads while the barrier remains stationary such that the barrier prevents the encapsulant from contacting the functional elements, removing the barrier when the bead of encapsulant has been deposited. The fluidic resistance generated by the gap between the barrier and the active surface means that the amount of encapsulant that flows into the gap and onto the active surface is almost constant.

Abstract: A method of forming an asymmetrical encapsulant bead on a series of wire bonds electrically connecting a micro-electronic device to a series of conductors, the micro-electronic device having a planar active surface. The method has the steps of positioning the die and the wire bonds beneath an encapsulant jetter that jets drops of encapsulant on to the wire bonds, the drops of encapsulant following a vertical trajectory, tilting the die such that the active surface is inclined to the horizontal and, jetting the drops of encapsulant to form a bead of encapsulant material covering the series of wire bonds, the bead having a cross sectional profile that is asymmetrical about an axis parallel to a normal to the active surface.

Abstract: A method of reducing voids within a bead of encapsulant material deposited on a series of wire bonds connecting a micro-electronic device with die contact pads extending along one edge, and a plurality of conductors on a support structure such that the wire bonds extend across a gap defined between the edge of the micro-electronic device and the plurality of conductors. The method has the steps of depositing at least one transverse bead of encapsulant in the gap extending at an angle to the edge of the micro-electronic device, and, depositing at least one longitudinal bead of encapsulant in the gap extending parallel to the edge of the micro-electronic device.

Abstract: A method of jetting drops of encapsulant from an encapsulant jetter, the drops including primary drops and satellite drops that are much smaller than the primary drops. The method has the steps of providing a series of wire bonds electrically connecting a micro-electronic device to a series of conductors, jetting the drops of encapsulant from the jetter and, inducing a gas flow with a velocity sufficient to draw the satellite drops in a predetermined direction away from the series of wire bonds while having negligible effect on the primary drops.

Abstract: A method of reducing voids within a bead of encapsulant material deposited on a series of wire bonds connecting a micro-electronic device with die contact pads extending along one edge, and a plurality of conductors on a support structure such that the wire bonds extend across a gap defined between the edge of the micro-electronic device and the plurality of conductors. The method has the steps of depositing at least one transverse bead of encapsulant in the gap extending at an angle to the edge of the micro-electronic device, and, depositing at least one longitudinal bead of encapsulant in the gap extending parallel to the edge of the micro-electronic device.

Abstract: A method of forming an asymmetrical encapsulant bead on a series of wire bonds electrically connecting a micro-electronic device to a series of conductors, the micro-electronic device having a planar active surface. The method has the steps of positioning the die and the wire bonds beneath an encapsulant jetter that jets drops of encapsulant on to the wire bonds, the drops of encapsulant following a vertical trajectory, tilting the die such that the active surface is inclined to the horizontal and, jetting the drops of encapsulant to form a bead of encapsulant material covering the series of wire bonds, the bead having a cross sectional profile that is asymmetrical about an axis parallel to a normal to the active surface.

Abstract: A method encapsulating wire bonds that extend between a die and conductors on a supporting substrate, by contacting an edge of a profiling blade with the encapsulant material to form a bead of the encapsulant on the edge, positioning the edge such that the bead contacts the die and, moving the profiling blade relative to the die to cover the wire bonds with the encapsulant. Wiping the encapsulant over the wire bonds with a profiling blade provides control of the encapsulant front as well as the height of the encapsulant relative to the die. The movement of the profiling surface relative to the die can closely controlled to shape the encapsulant to a desired form. Using the example of a printhead die, the encapsulant can be shaped to present an inclined face rising from the nozzle surface to a high point over the wire bonds. This can be used by the printhead maintenance facilities to maintain contact pressure on the wiping mechanism.

Abstract: A method of profiling a series of wire bonds between a line of contact pads on a die, and a corresponding set of conductors on a supporting structure, by electrically connecting each of the contact pads on the die to a corresponding conductor on the supporting structure with a respective wire bond, each of the wire bonds extending in an arc from the contact pad to the conductor, and, pushing on each of the wire bonds individually to collapse the arc and plastically deform the wire bond such that the plastic deformation maintains the wire bond in a flatter profile shape.

Abstract: A method of applying encapsulant to a die mounted to a support structure by providing a die mounted to the support structure, the die having a back surface in contact with the support structure and an active surface opposing the back surface, the active surface having electrical contact pads, positioning a barrier proximate the electrical contact pads and spaced from the active surface to define a gap and, depositing a bead of encapsulant onto the electrical contact pads such that one side of the bead contacts the barrier and a portion of the bead extends into the gap and onto the active surface. Placing a barrier over the active surface so that it defines a narrow gap allows the geometry of the encapsulant front (the line of contact between the encapsulant and the active surface) can be more closely controlled. Any variation in the flowrate of encapsulant from the needle tends to cause bulges or valleys in the height of the bead and or the PCB side of the bead.

Abstract: A prosthetic hearing implant kit is disclosed. The prosthetic hearing implant kit comprises internal components configured to be implanted in a recipient and comprises an internal coil; external components configured to be worn by the recipient and comprises an external coil adapted to be inductively coupled with said internal coil; and an alert system having a second external coil and adapted to receive an external alarm and to transmit signals to said implanted components via said external coil for providing the recipient with a corresponding alarm indication.

Abstract: A method of applying encapsulant to wire bonds between a die and conductors on a supporting substrate, by forming a bead of the encapsulant on a profiling surface, positioning the profiling surface such that the bead contacts the die and, moving the profiling surface relative to the die to cover the wire bonds with the encapsulant. Wiping the encapsulant over the wire bonds with a profiling surface provides control of the encapsulant front as well as the height of the encapsulant relative to the die. The movement of the profiling surface relative to the die can closely controlled to shape the encapsulant to a desired form. Using the example of a printhead die, the encapsulant can be shaped to present an inclined face rising from the nozzle surface to a high point over the wire bonds. This can be used by the printhead maintenance facilities to maintain contact pressure on the wiping mechanism.

Abstract: A prosthetic hearing implant kit is disclosed. The prosthetic hearing implant kit comprises internal components configured to be implanted in a recipient and comprises an internal coil; external components configured to be worn by the recipient and comprises an external coil adapted to be inductively coupled with said internal coil; and an alert system having a second external coil and adapted to receive an external alarm and to transmit signals to said implanted components via said external coil for providing the recipient with a corresponding alarm indication.

Abstract: An electronic component that has a support structure with a plurality of electrical conductors, a series of wire bonds, each of the wire bonds extending from one of the electrical conductors respectively, each of the wire bonds having an end section contacting the electrical conductor and an intermediate section contiguous with the end section, a bead of dam encapsulant encapsulating the electrical conductors and the end section of each of the wire bonds, and a bead of fill encapsulant contacting the bead of dam encapsulant and encapsulating the intermediate portion of each of the wire bonds. The dam encapsulant has a higher modulus of elasticity than the fill encapsulant.

Abstract: A method of applying encapsulant to a die mounted to a support structure by providing a die mounted to the support structure, the die having a back surface in contact with the support structure and an active surface opposing the back surface, the active surface having electrical contact pads, positioning a barrier proximate the electrical contact pads and spaced from the active surface to define a gap and, depositing a bead of encapsulant onto the electrical contact pads such that one side of the bead contacts the barrier and a portion of the bead extends into the gap and onto the active surface. Placing a barrier over the active surface so that it defines a narrow gap allows the geometry of the encapsulant front (the line of contact between the encapsulant and the active surface) can be more closely controlled. Any variation in the flowrate of encapsulant from the needle tends to cause bulges or valleys in the height of the bead and or the PCB side of the bead.

Abstract: A method of profiling a series of wire bonds between a line of contact pads on a die, and a corresponding set of conductors on a supporting structure, by electrically connecting each of the contact pads on the die to a corresponding conductor on the supporting structure with a respective wire bond, each of the wire bonds extending in an arc from the contact pad to the conductor, and, pushing on each of the wire bonds individually to collapse the arc and plastically deform the wire bond such that the plastic deformation maintains the wire bond in a flatter profile shape.

Abstract: An electronic device that has an integrated circuit die with a plurality of contacts pads, a printed circuit board with a plurality of conductors corresponding to each of the contact pads respectively, wire bonds electrically connecting each of the contact pads to the corresponding conductors and, an adhesive surface positioned between the contacts pads and the corresponding conductors. The wire bonds are secured to the adhesive surface to hold them in a low profile configuration.

Abstract: A microprocessor device that has a support structure with a chip mounting area and a conductor mounting area. An inkjet printhead IC is supported on the chip mounting area. The inkjet printhead IC has a back surface in contact with the chip mounting area and an active surface opposing the back surface. The active surface has electrical contact pads and an array of ink ejection nozzles. The active surface has electrical contact pads for its circuitry and functional elements. A plurality of electrical conductors are, at least partially, supported on the conductor mounting area and a series of wire bonds extending from the electrical contact pads to the plurality of electrical conductors supported on the conductor mounting area wherein, the chip mounting area is raised relative to the conductor mounting area.

Abstract: A method of profiling a wire bond between a contact pad on a die, and a conductor on a supporting structure, by electrically connecting the contact pad on the die to the conductor on the supporting structure with a wire bond, the wire bond extending in an arc from the contact pad to the conductor, pushing on the wire bond to collapse the arc and plastically deform the wire bond, and then releasing the wire bonds such that the plastic deformation maintains the wire bond in a flatter profile shape. The strength of the wire bond is known to be relatively small; of the order of 3 to 5 grams force. However, the Applicant's work has found that the wire bond structure is robust enough to withstand a certain degree of work hardening from plastic deformation. The arc of the wire bond can be deformed into a flatter profile without compromising the electrical connection with the PCB.

Abstract: A method for profiling a bead of encapsulant extending along an edge of a die mounted to a supporting structure, by depositing a bead of encapsulant onto wire bonds along the edge of the die, positioning a profiling surface over the die at a predetermined spacing from the die, moving the profiling surface across the bead before the bead of encapsulant has cured to reshape the bead profile and, curing the bead of encapsulant. The invention has found that the encapsulant can be effectively shaped by a profiling surface without stripping the encapsulant from the wire bonds. The normally convex-shaped upper surface of the encapsulant bead can be pushed to one side of the bead with the profiling surface. With a lower encapsulant bead, the active surface can be brought into closer proximity with another surface without making contact. For example, the nozzle array on a printhead IC can be 300 microns to 400 microns from the paper path.

Abstract: A method of applying encapsulant to wire bonds between a die and conductors on a supporting substrate, by forming a bead of the encapsulant on a profiling surface, positioning the profiling surface such that the bead contacts the die and, moving the profiling surface relative to the die to cover the wire bonds with the encapsulant. Wiping the encapsulant over the wire bonds with a profiling surface provides control of the encapsulant front as well as the height of the encapsulant relative to the die. The movement of the profiling surface relative to the die can closely controlled to shape the encapsulant to a desired form. Using the example of a printhead die, the encapsulant can be shaped to present an inclined face rising from the nozzle surface to a high point over the wire bonds. This can be used by the printhead maintenance facilities to maintain contact pressure on the wiping mechanism.