A bonding apparatus includes a bonding stage on which either a rectangular substrate or a circular substrate can be installed; a first transport mechanism which transports the rectangular substrate from a first carry-in unit to the bonding stage and from the bonding stage to a first carry-out unit; and a second transport mechanism which transports the circular substrate from a second carry-in/out unit to the bonding stage and from the bonding stage to the second carry-in/out unit, in which a first transport path determined by the first transport mechanism and a second transport path determined by the second transport mechanism partially overlap.

A package structure includes a redistribution structure, a first semiconductor die, a first passive component, a second semiconductor die, a first insulating encapsulant, a second insulating encapsulant, a second passive component and a global shielding structure. The redistribution structure includes dielectric layers and conductive layers alternately stacked. The first semiconductor die, the first passive component and the second semiconductor die are disposed on a first surface of the redistribution structure. The first insulating encapsulant is encapsulating the first semiconductor die and the first passive component. The second insulating encapsulant is encapsulating the second semiconductor die, wherein the second insulating encapsulant is separated from the first insulating encapsulant. The second passive component is disposed on a second surface of the redistribution structure. The global shielding structure is surrounding the first insulating encapsulant, the second insulating encapsulant, and covering sidewalls of the redistribution structure.

An electronic module can include a first integrated device package comprising a first substrate and an electronic component mounted to the first substrate. A first vertical interconnect can be mounted to and electrically connected to the first substrate. The first vertical interconnect can extend outwardly from the first substrate. The electronic module can include a second integrated device package comprising a second substrate and a second vertical interconnect having a first end mounted to and electrically connected to the second substrate. The second vertical interconnect can have a second end electrically connected to the first vertical interconnect. The first and second vertical interconnects can be disposed between the first and second substrates.

A disclosed apparatus may include (1) an integrated circuit electrically coupled to a substrate, (2) a plurality of electrical contacts that are disposed on the substrate and are electrically coupled to the integrated circuit via the substrate, (3) at least one cable assembly electrically coupled to the plurality of electrical contacts, and (4) a package stiffener physically coupled to the substrate around the integrated circuit such that the at least one cable assembly is accessible to at least one electrical cable. Various other apparatuses, systems, and methods are also disclosed.

A micro-component module comprises a module substrate, a component disposed on the module substrate, and at least a portion of a module tether in contact with the module substrate. The module substrate can be flexible or can comprise an organic material, or both. The module tether can be more brittle and less flexible than the module substrate. The component can be less flexible than the module substrate and can comprise at least a portion of a component tether. An encapsulation layer can be disposed over the component and module substrate. The component can be disposed in a mechanically neutral stress plane of the micro-component module. A micro-component module system can comprise a micro-component module disposed on a flexible system substrate, for example by micro-transfer printing. A micro-component module can comprise an internal module cavity in the module substrate with internal module tethers physically connecting the module substrate to internal anchors.

A disclosed apparatus may include (1) an integrated circuit electrically coupled to a substrate, (2) a plurality of electrical contacts that are disposed on the substrate and are electrically coupled to the integrated circuit via the substrate, (3) at least one cable assembly electrically coupled to the plurality of electrical contacts, and (4) a package stiffener physically coupled to the substrate around the integrated circuit such that the at least one cable assembly is accessible to at least one electrical cable. Various other apparatuses, systems, and methods are also disclosed.

A package structure includes a redistribution structure, a first semiconductor die, a first passive component, a second semiconductor die, a first insulating encapsulant, a second insulating encapsulant, a second passive component and a global shielding structure. The redistribution structure includes dielectric layers and conductive layers alternately stacked. The first semiconductor die, the first passive component and the second semiconductor die are disposed on a first surface of the redistribution structure. The first insulating encapsulant is encapsulating the first semiconductor die and the first passive component. The second insulating encapsulant is encapsulating the second semiconductor die, wherein the second insulating encapsulant is separated from the first insulating encapsulant. The second passive component is disposed on a second surface of the redistribution structure. The global shielding structure is surrounding the first insulating encapsulant, the second insulating encapsulant, and covering sidewalls of the redistribution structure.

Systems and methods for a semiconductor device having an edge-notched substrate are provided. The device generally includes a substrate having a front side, a backside having substrate contacts, and an inward notch at an edge of the substrate. The device includes a die having an active side attached to the front side of the substrate and positioned such that bond pads of the die are accessible from the backside of the substrate through the inward notch. The device includes wire bonds routed through the inward notch and electrically coupling the bond pads of the die to the substrate contacts. The device may further include a second die having an active side attached to the backside of the first die and positioned laterally offset from the first die such that the second bond pads are accessible by wire bonds around the edge of the first die and through the inward notch.

An electronic element mounting substrate according to the present disclosure includes a base body having a recessed portion including a mounting region on which an electronic element is mounted and a cutout section located on an outer periphery of the base body in a plane perspective, and a channel having an inner end portion located on an inner wall of the base body and an outer end portion located on the outer periphery of the base body. The inner end portion of the channel is open to the recessed portion, and the outer end portion of the channel is continuous with the cutout section.

A die-wrapped packaged device includes at least one flexible substrate having a top side and a bottom side that has lead terminals, where the top side has outer positioned die bonding features coupled by traces to through-vias that couple through a thickness of the flexible substrate to the lead terminals. At least one die includes a substrate having a back side and a topside semiconductor surface including circuitry thereon having nodes coupled to bond pads. One of the sides of the die is mounted on the top side of the flexible circuit, and the flexible substrate has a sufficient length relative to the die so that the flexible substrate wraps to extend over at least two sidewalls of the die onto the top side of the flexible substrate so that the die bonding features contact the bond pads.