Abstract: In a described example, a method includes loading at least one package substrate strip including electronic device dies mounted on the at least one package substrate strip into a plasma process chamber; positioning at least one E-field shield in the plasma process chamber spaced from and over the at least one package substrate strip; and plasma cleaning the at least one package substrate strip.

Abstract: An apparatus includes a first die attach pad and a second die attach pad. A first die is attached to the first die attach pad and a second die is attached to the second die attach pad. The first die attach pad and the second die attach pad are separated by a gap. A first edge of the first die attach pad adjacent to the gap is thinner than a second edge of the first die attach pad. The first edge of the first die attach pad is opposite the second edge of the first die attach pad. A first edge of the second die attach pad adjacent to the gap is thinner than a second edge of the second die attach pad. The first edge of the second die attach pad is opposite the second edge of the second die attach pad.

Abstract: A leadframe includes leads or lead terminals, a plurality of folded features including i) support features positioned within an area defined in at least one dimension by the leads or the lead terminals configured for supporting at least one of a die pad and a first pad and a second pad spaced apart from one another, or ii) current carrying features. At least one of the folded features includes a planar portion and a folded edge structure that curves upwards at an angle of at least 45° relative to the planar portion. The folded features are configured to provide an effective increase in thickness to reduce the deformation observed in assembly.

Abstract: An integrated circuit testing assembly that includes: (i) a first slug configured to contact a first surface of a first set of pins of an integrated circuit; (ii) a second slug configured to contact a second surface of the first set of pins of the integrated circuit; (iii) a third slug configured to contact a first surface of a second set of pins of the integrated circuit; and (iv) a fourth slug configured to contact a second surface of the second set of pins of the integrated circuit.

Abstract: A semiconductor device includes a semiconductor surface having circuitry with metal interconnect layers over the semiconductor surface including a selected metal interconnect layer providing an interconnect trace having a first and second end. A top dielectric layer is on the top metal interconnect layer. A redistribution layer (RDL) is on the top dielectric layer. A corrosion interruption structure (CIS) including the interconnect trace bridges an interrupting gap in a trace of the RDL.

Abstract: In described examples of an isolation device, an isolation die that has a set of bond pads is mounted on a first lead frame that has a set of leads. A portion of the bond pads are coupled to respective leads. A first mold material encapsulates the isolation device and the first lead frame forming a first package. The first package is mounted on a second lead frame that has a set of leads. A portion of the first lead frame leads is coupled to respective ones of the second lead frame leads. A second mold material encapsulates the first package and the second lead frame.

Abstract: A Hall-effect sensor package includes and an IC die including a Hall-Effect element and a leadframe including leads on a first side providing a first field generating current (FGC) path including ?1 first FGC input pin coupled by a reduced width first curved head over or under the Hall-effect sensor element to ?1 first FGC output pin, and second leads on a second side of the package. Some leads on the second side are attached to bond pads on the IC die including the output of the Hall-effect element. A clip is attached at one end to the first FGC input pin and at another end to a location on the first FGC output pin, having a reduced width second curved head in between that is over or under the Hall-effect sensor element opposite the first head.

Abstract: A method of manufacturing a semiconductor package includes covering a semiconductor die and a plurality of conductive terminals coupled to the semiconductor die in a mold compound, positioning the mold compound between a first pair of electrodes and a second pair of electrodes, and moving a movable electrode of the first pair and a movable electrode of the second pair into a first clamping position. In the first clamping position, each of the first pair of electrodes and the second pair of electrodes electrically couples to a unique subset of the plurality of conductive terminals. The method also includes applying, by the first pair of electrodes, a first voltage to the semiconductor die within the mold compound; and applying, by the second pair of electrodes, a second voltage to the semiconductor die within the mold compound. The second voltage is less than the first voltage.

Abstract: An apparatus includes a first die attach pad and a second die attach pad. A first die is attached to the first die attach pad and a second die is attached to the second die attach pad. The first die attach pad and the second die attach pad are separated by a gap. A first edge of the first die attach pad adjacent to the gap is thinner than a second edge of the first die attach pad. The first edge of the first die attach pad is opposite the second edge of the first die attach pad. A first edge of the second die attach pad adjacent to the gap is thinner than a second edge of the second die attach pad. The first edge of the second die attach pad is opposite the second edge of the second die attach pad.

Abstract: Described examples include a sensor device having at least one conductive elongated first pillar positioned on a central pad of a first conductor layer over a semiconductor substrate, the first pillar extending in a first direction normal to a plane of a surface of the first conductor layer. Conductive elongated second pillars are positioned in normal orientation on a second conductor layer over the semiconductor substrate, the conductive elongated second pillars at locations coincident to via openings in the first conductor layer. The second conductor layer is parallel to and spaced from the first conductor layer by at least an insulator layer, the conductive elongated second pillars extending in the first direction through a respective one of the via openings. The at least one conductive elongated first pillar is spaced from surrounding conductive elongated second pillars by gaps.

Abstract: A Hall-effect sensor package includes and an IC die including a Hall-Effect element and a leadframe including leads on a first side providing a first field generating current (FGC) path including ?1 first FGC input pin coupled by a reduced width first curved head over or under the Hall-effect sensor element to ?1 first FGC output pin, and second leads on a second side of the package. Some leads on the second side are attached to bond pads on the IC die including the output of the Hall-effect element. A clip is attached at one end to the first FGC input pin and at another end to a location on the first FGC output pin, having a reduced width second curved head in between that is over or under the Hall-effect sensor element opposite the first head.

Abstract: Described examples include a sensor device having at least one conductive elongated first pillar positioned on a central pad of a first conductor layer over a semiconductor substrate, the first pillar extending in a first direction normal to a plane of a surface of the first conductor layer. Conductive elongated second pillars are positioned in normal orientation on a second conductor layer over the semiconductor substrate, the conductive elongated second pillars at locations coincident to via openings in the first conductor layer. The second conductor layer is parallel to and spaced from the first conductor layer by at least an insulator layer, the conductive elongated second pillars extending in the first direction through a respective one of the via openings. The at least one conductive elongated first pillar is spaced from surrounding conductive elongated second pillars by gaps.

Abstract: A microelectronic device includes a first conductor and a second conductor, separated by a lateral spacing. The first conductor has a low field contour facing the second conductor. The low field contour has offsets from a tangent line to the first conductor on the low field contour. Each of the offsets increases a separation of the high voltage conductor from the low voltage conductor. A first offset, located from an end of the high voltage conductor, at a first lateral distance of 25 percent of the minimum separation, is 19 percent to 28 percent of the minimum separation. A second offset, located at a second lateral distance of 50 percent of the minimum separation, is 9 percent to 14 percent of the minimum separation. A third offset, located at a third lateral distance of 75 percent of the minimum separation, is 4 percent to 6 percent of the minimum separation.

Abstract: A Hall-effect sensor package includes and an IC die including a Hall-Effect element and a leadframe including leads on a first side providing a first field generating current (FGC) path including ?1 first FGC input pin coupled by a reduced width first curved head over or under the Hall-effect sensor element to ?1 first FGC output pin, and second leads on a second side of the package. Some leads on the second side are attached to bond pads on the IC die including the output of the Hall-effect element. A clip is attached at one end to the first FGC input pin and at another end to a location on the first FGC output pin, having a reduced width second curved head in between that is over or under the Hall-effect sensor element opposite the first head.

Abstract: A microelectronic device includes a first conductor and a second conductor, separated by a lateral spacing. The first conductor has a low field contour facing the second conductor. The low field contour has offsets from a tangent line to the first conductor on the low field contour. Each of the offsets increases a separation of the high voltage conductor from the low voltage conductor. A first offset, located from an end of the high voltage conductor, at a first lateral distance of 25 percent of the minimum separation, is 19 percent to 28 percent of the minimum separation. A second offset, located at a second lateral distance of 50 percent of the minimum separation, is 9 percent to 14 percent of the minimum separation. A third offset, located at a third lateral distance of 75 percent of the minimum separation, is 4 percent to 6 percent of the minimum separation.

Abstract: An apparatus includes a first die attach pad and a second die attach pad. A first die is attached to the first die attach pad and a second die is attached to the second die attach pad. The first die attach pad and the second die attach pad are separated by a gap. A first edge of the first die attach pad adjacent to the gap is thinner than a second edge of the first die attach pad. The first edge of the first die attach pad is opposite the second edge of the first die attach pad. A first edge of the second die attach pad adjacent to the gap is thinner than a second edge of the second die attach pad. The first edge of the second die attach pad is opposite the second edge of the second die attach pad.

Abstract: Described examples include a sensor device having at least one conductive elongated first pillar positioned on a central pad of a first conductor layer over a semiconductor substrate, the first pillar extending in a first direction normal to a plane of a surface of the first conductor layer. Conductive elongated second pillars are positioned in normal orientation on a second conductor layer over the semiconductor substrate, the conductive elongated second pillars at locations coincident to via openings in the first conductor layer. The second conductor layer is parallel to and spaced from the first conductor layer by at least an insulator layer, the conductive elongated second pillars extending in the first direction through a respective one of the via openings. The at least one conductive elongated first pillar is spaced from surrounding conductive elongated second pillars by gaps.

Abstract: An assembly including an electrical connection substrate formed of material having a Young's modulus of less than about 10 MPa, an acoustic device die having opposite end portions mounted on and electrically connected to the electrical connection substrate and a mold compound layer encapsulating the acoustic device die and interfacing with the substrate.

Abstract: An assembly including an electrical connection substrate formed of material having a Young's modulus of less than about 10 MPa, an acoustic device die having opposite end portions mounted on and electrically connected to the electrical connection substrate and a mold compound layer encapsulating the acoustic device die and interfacing with the substrate.

Abstract: Described examples include a packaged device including a first object and a second object spaced from each other by a gap, each object having a first surface and an opposite second surface, the first surfaces of the first object and the second object including first terminals. A structure includes at least two conductors embedded in a dielectric casing consolidating a configuration and organization of the at least two conductors, the at least two conductors having end portions un-embedded by the dielectric casing. An end portion of at least one of the at least two conductors is electrically connected to a first terminal of the first object, and an opposite end portion of the at least one of the at least two conductors is electrically connected to a respective first terminal of the second object, the at least two conductors electrically connecting the first object and the second object.