Abstract: A chip package includes a substrate, a pad, a double-sided adhesive tape, a chip, and a sealing member. The pad is arranged on the substrate and has a top surface facing away from the substrate. The double-sided adhesive tape includes a first paste surface and an opposing second paste surface. The first paste surface is attached to the top surface. The chip is attached onto the second paste surface and includes a light emitting surface or a light receiving surface facing away from the second paste surface. The sealing member is formed on the pad and tightly surrounds the chip and the double-sided adhesive.

Abstract: A method for fabricating a stackable integrated circuit layer and a device made from the method are disclosed. A stud bump is defined on the contact pad of an integrated circuit die and the stud-bumped die encapsulated in a potting material to define a potted assembly. A predetermined portion of the potting material is removed whereby a portion of the stud bump is exposed. One or more electrically conductive traces are defined on the layer surface and in electrical connection with the stud bump to reroute the integrated circuit contacts to predetermined locations on the layer to provide a stackable neolayer.

Abstract: Provided are a double-sided adhesive tape, semiconductor packages, and methods of fabricating the packages. A method of fabricating semiconductor packages includes providing a double-sided adhesive tape on a top surface of a carrier, the double-sided adhesive tape including a first adhesive layer and a second adhesive layer stacked on the first adhesive layer, the first adhesive layer of the double-sided adhesive tape being in contact with the top surface of the carrier, adhering active surfaces of a plurality of semiconductor chips onto the second adhesive layer of the double-sided adhesive tape, separating the first adhesive layer from the second adhesive layer such that the second adhesive layer remains on the active surfaces of the semiconductor chips, patterning the second adhesive layer to form first openings that selectively expose the active surfaces of the semiconductor chips, and forming first conductive components on the second adhesive layer to fill the first openings.

Abstract: This IC card is provided with a module having an inlet, an adhesive layer covering the module, and a first base material and second base material sandwiching the module with interposition of the adhesive layer. The module is disposed on one face of the first base material with interposition of a viscous layer which has a thickness that varies according to the thickness at each area of the module, and its two ends are narrower than its other parts when viewed from the outer face side of the first base material or the outer face side of the second base material. According to this IC card, it is possible to offer the IC card with a flat surface, and without occurrence of strain in the embedded IC chip.

Abstract: The present technology discloses a multi-die package. The package comprises a lead frame structure and three dies including a first flip chip die, a second flip chip die and a third flip chip die stacked vertically. The first flip chip die is mounted on the bottom surface of the lead frame structure through the flip chip bumps; the second flip chip is mounted on the top surface of the first flip chip die through flip chip bumps; and the third flip chip die is mounted on the top surface of the lead frame structure through flip chip bumps.

Abstract: A method of manufacture of an integrated circuit packaging system includes: fabricating a base package substrate having a component side and a system side; coupling stacking interconnects on the component side; and forming an integrated circuit receptacle, for receiving an integrated circuit device, by molding a reinforced encapsulant on the component side and exposing a portion of the stacking interconnects.

Abstract: Present embodiments are directed to an adhesive and method for assembling a chip package. The adhesive may be used to couple a chip to a substrate, and the adhesive may include an epoxy-based dielectric material, an epoxy resin, a photoacid generator, an antioxidant, and a cold catalyst corresponding to the photoacid generator.

Abstract: A 3D system-level packaging method includes providing a packaging substrate, forming a glue layer on the substrate, and attaching a first chip layer at an opposite side of a functional surface of the first chip layer on the packaging substrate through the glue layer. The method also includes forming a first sealant layer on the packaging substrate at a same side attached with the first chip layer and exposing bonding pads of the first chip layer. The method also includes forming first vias in the first sealant layer, forming first vertical metal wiring in the first vias, and forming a first horizontal wiring layer on the sealant layer interconnecting the first chip layer and the first vertical metal wiring. Further, the method includes forming a plurality of package layers on the first sealant layer, and each of the plurality of package layers includes a chip layer, a sealant layer covering the chip layer, and vertical metal wiring and a horizontal wiring layer interconnecting adjacent package layers.

Abstract: A packaged semiconductor device may include a termination surface having terminations configured as leadless interconnects to be surface mounted to a printed circuit board. A first flange has a first surface and a second surface. The first surface provides a first one of the terminations, and the second surface is opposite to the first surface. A second flange also has a first surface and a second surface, with the first surface providing a second one of the terminations, and the second surface is opposite to the first surface. A die is mounted to the second surface of the first flange with a material having a melting point in excess of 240° C. An electrical interconnect extends between the die and the second surface of the second flange opposite the termination surface, such that the electrical interconnect, first flange and second flange are substantially housed within a body.

Abstract: Microelectronic devices and methods for manufacturing microelectronic devices are disclosed herein. In one embodiment, a microelectronic device includes a microelectronic die, a plurality of electrical couplers projecting from the die, and a flowable material disposed on the die. The die includes an integrated circuit and a plurality of terminals operably coupled to the integrated circuit. The electrical couplers are attached to corresponding terminals on the die. The flowable material includes a plurality of spacer elements sized to space the die apart from another component. The flowable material may be a no-flow underfill, a flux compound, or other suitable material.

Abstract: An assembly has at least one integrated circuit (IC) die fixed in a medium. The assembly has a redistribution layer over the IC die. The redistribution layer has conductors connecting first pads on active faces of the IC die to second pads at an exposed surface of the assembly. A die unit is provided over the IC die. The die unit has a bottom die interconnected to a package substrate. Respective portions of the redistribution layer corresponding to each of the at least one IC die partially underlie the bottom die, and extend beyond the bottom die. The package substrate has contacts connected to the ones of the second pads corresponding to the at least one IC die.

Abstract: A method of manufacturing a modular semiconductor subassembly: providing at least one semiconductor subassembly having a modular sidewall element of modular dimensions and a semiconductor substrate base element coupled to the modular sidewall element that has at least one semiconductor element with a layout sized to be accommodated by modular dimensions of the modular sidewall element. If a modular package protective cover is to be used: providing the modular package protective cover configured to accommodate the semiconductor subassembly in accordance with a modular design; securing the semiconductor subassembly in the modular package protective cover to create a modular package assembly; and mounting the modular package assembly to a core, with a base side of the semiconductor substrate base element in contact with the core; otherwise: mounting the at semiconductor subassembly to the core, with the base side of the semiconductor substrate base element in contact with the core.

Abstract: A method (30) of forming a semiconductor package (20) entails applying (56) an adhesive (64) to a portion (66) of a bonding perimeter (50) of a base (22), with a section (68) of the perimeter (50) being without the adhesive (64). A lid (24) is placed on the base (22) so that a bonding perimeter (62) of the lid (24) abuts the bonding perimeter (50) of the base (22). The lid (24) includes a cavity (25) in which dies (38) mounted to the base (22) are located. A gap (70) is formed without the adhesive (64) at the section (68) between the base (22) and the lid (24). The structure vents from the gap (70) as air inside the cavity (25) expands during heat curing (72). Following heat curing (72), another adhesive (80) is dispensed in the section (68) to close the gap (70) and seal the cavity (25).

Abstract: The method includes the steps of: providing a lead frame, including providing a concaved part in an upper face of a joint part of a die-pad-support lead of a lead frame for setting down a die pad and a tie-bar; bonding a semiconductor chip to a first principal face of the die pad via an adhesive-member layer; then, setting the lead frame between first and second molding dies having first and second cavities respectively so that the first and second cavities are opposed to each other, and the second principal face of the die pad faces toward the second cavity; and forming first and second resin sealed bodies on the sides of the first and second principal faces of the die pad respectively by resin sealing with the first and second molding dies clamping the tie-bar and a part of the lead frame surrounding the tie-bar.

Abstract: A curable one-part epoxy resin composition is described. The composition comprises an epoxy component comprising at least one epoxy compound which has two or more groups per molecule; a latent hardener component; a thixotropy-conferrring component; a polythiol component comprising a polythiol having at least one secondary or tertiary thiol group per molecule; and a stabilising component comprising a solid organic acid. The compositions according to the invention are particularly suitable for use in the field of microelectronics.

Abstract: In one embodiment, a semiconductor structure including a first substrate, a semiconductor device on the first substrate, a second substrate, and a conductive bond between the first substrate and the second substrate that surrounds the semiconductor device to seal the semiconductor device between the first substrate and the second substrate. The conductive bond comprises metal, silicon, and germanium. A percentage by atomic weight of silicon in the conductive bond is greater than 5%.

Abstract: There are disclosed herein various implementations of improved wafer level semiconductor packages. One exemplary implementation comprises forming a post-fabrication redistribution layer (post-Fab RDL) between first and second dielectric layers affixed over a surface of a wafer, and forming a window for receiving an electrical contact body in the second dielectric layer, the window exposing the post-Fab RDL. At least one of the first and second dielectric layers is a pre-formed dielectric layer, which may be affixed over the surface of the wafer using a lamination process. In one implementation, the window is formed using a direct laser ablation process.

Abstract: A semiconductor package includes a semiconductor structure. The semiconductor structure includes a plurality of dielectric layers and a plurality of conductive interconnects embedded in the semiconductor structure. The semiconductor structure also includes a plurality of proximity communication signal input terminals. At least one of the plurality of proximity communication signal input terminals includes a first electrode and a second electrode. The first electrode and the second electrode are spaced apart so as to be configured to provide proximity communication through capacitive coupling. The first electrode is exposed proximate to a surface of the semiconductor structure.

Abstract: A method of mounting a semiconductor die on a substrate with a solder mask on a first surface includes placing a die on the solder mask, and mounting the die to the substrate by applying pressure and heat. The applied pressure ranges from a bond force of approximately 5 to 10 kgf, the heat has a temperature range from approximately 150 to 200° C. and the pressure is applied for a range of approximately 1 to 10 seconds.

Abstract: Various methods of attaching a lid to an integrated circuit substrate are provided. In one aspect, a method of attaching a lid to a substrate that has an integrated circuit positioned thereon is provided. An adhesive is applied to the substrate and an indium film is applied to the integrated circuit. The lid is positioned on the adhesive. The adhesive is partially hardened and the indium film is reflowed. The adhesive is cured.

Abstract: A device includes an interposer, which includes a substrate; and at least one dielectric layer over the substrate. A plurality of through-substrate vias (TSVs) penetrate through the substrate. A first metal bump is in the at least one dielectric layer and electrically coupled to the plurality of TSVs. A second metal bump is over the at least one dielectric layer. A die is embedded in the at least one dielectric layer and bonded to the first metal bump.

Abstract: Provided is a technology of suppressing, in forming an initial ball by using an easily oxidizable conductive wire and pressing the initial ball onto a pad to form a press-bonded ball, an initial ball from having a shape defect, thereby reducing damage to the pad. To achieve this, a ball formation unit is equipped with a gas outlet portion for discharging an antioxidant gas and a discharging path through this gas outlet portion is placed in a direction different from a direction of introducing the antioxidant gas into a ball formation portion. Such a structure widens a region for discharging the antioxidant gas, making it possible to prevent a gas flow supplied from the side of one side surface of the ball formation portion from being reflected by the other side surface facing with the one side surface and thereby forming a turbulent flow.

Abstract: A method for manufacturing a filling in a gap region between a first surface and a second surface includes applying a suspension comprising a carrier fluid and filler particles in the gap region between the first and the second surface; and withholding filler particles by a barrier element in the gap region to form a path of attached filler particles between the first surface and the second surface.

Abstract: Methods for forming semiconductor device packages include applying a photoimageable dielectric adhesive material to a major surface of a semiconductor die and at least partially over conductive elements on the semiconductor die. The photoimageable dielectric adhesive material may be removed from over the conductive elements. The conductive elements are aligned with and bonded to bond pads of a substrate, and the semiconductor die and the substrate are adhered with the photoimageable dielectric adhesive material. A semiconductor device package includes at least one semiconductor die including conductive structures thereon, a substrate including bond pads thereon that are physically and electrically connected to the conductive structures, and a developed photoimageable dielectric adhesive material disposed between the semiconductor die and the substrate around and between adjacent conductive structures.

Abstract: An optical modulator includes an input port, a first waveguide region comprising silicon and optically coupled to the input port, and a waveguide splitter optically coupled to the first waveguide region and having a first output and a second output. The optical modulator also includes a first phase adjustment section optically coupled to the first output and comprising a first III-V diode and a second phase adjustment section optically coupled to the second output and comprising a second III-V diode. The optical modulator further includes a waveguide coupler optically coupled to the first phase adjustment section and the second phase adjustment section, a second waveguide region comprising silicon and optically coupled to the waveguide coupler, and an output port optically coupled to the second waveguide region.

Abstract: The present invention relates to a packaging method including the steps: a cementing layer is formed on a carrier board; the functional sides of chips and passive devices are attached to the cementing layer; a sealing material layer is formed on the side of the carrier board to which the chips and the passive devices are attached, and packaging and curing are performed; and the carrier board and the cementing layer are removed. Compared to the prior art, the system-level fan-out wafer packaging method claimed by the present invention first integrates chips and passive devices and then packages the chips and the passive devices together, thereby forming a final packaged product having not single-chip functionality but integrated-system functionality.

Abstract: A method of singulating a plurality of semiconductor dies includes providing a carrier substrate and joining a semiconductor substrate to the carrier substrate. The semiconductor substrate includes a plurality of devices. The method also includes forming a mask layer on the semiconductor substrate, exposing a predetermined portion of the mask layer to light, and processing the predetermined portion of the mask layer to form a predetermined mask pattern on the semiconductor substrate. The method further includes forming the plurality of semiconductor dies, each of the plurality of semiconductor dies being associated with the predetermined mask pattern and including one or more of the plurality of devices and separating the plurality of semiconductor dies from the carrier substrate.

Abstract: Even when a stiffener is omitted, the semiconductor device which can prevent the generation of twist and distortion of a wiring substrate is obtained. As for a semiconductor device which has a wiring substrate, a semiconductor chip by which the flip chip bond was made to the wiring substrate, and a heat spreader adhered to the back surface of the semiconductor chip, and which omitted the stiffener for reinforcing a wiring substrate and maintaining the surface smoothness of a heat spreader, a wiring substrate has a plurality of insulating substrates in which a through hole whose diameter differs, respectively was formed, and each insulating substrate contains a glass cloth.

Abstract: A method for producing a semiconductor device, including a semiconductor chip, for improving production efficiency and the flexibility of production design is provided.

Abstract: The thermosetting die-bonding film of the present invention is used in manufacturing a semiconductor device, has at least an epoxy resin, a phenol resin, and an acrylic copolymer, and the ratio X/Y is 0.7 to 5 when X represents a total weight of the epoxy resin and the phenol resin and Y represents a weight of the acrylic copolymer.

Abstract: A method includes providing a carrier with an adhesive layer disposed thereon; and providing a die including a first surface, a second surface opposite the first surface. The die further includes a plurality of bond pads adjacent the second surface; and a dielectric layer over the plurality of bond pads. The method further includes placing the die on the adhesive layer with the first surface facing toward the adhesive layer and dielectric layer facing away from the adhesive layer; forming a molding compound to cover the die, wherein the molding compound surrounds the die; removing a portion of the molding compound directly over the die to expose the dielectric layer; and forming a redistribution line above the molding compound and electrically coupled to one of the plurality of bond pads through the dielectric layer.

Abstract: A semiconductor device includes a passivation layer, a first protective layer, an interconnect layer, and a second protective layer successively formed on a semiconductor substrate. The interconnect layer has an exposed portion, on which a barrier layer and a solder bump are formed. At least one of the passivation layer, the first protective layer, the interconnect layer and the second protective layer includes at least one slot formed in a region outside a conductive pad region.

Abstract: A wafer-level process for fabricating a plurality of photoelectric modules is provided. The wafer-level process includes at least following procedures. Firstly, a wafer including a plurality of chips arranged in an array is provided. Next, a plurality of photoelectric devices are mounted on the chips. Next, a cover plate including a plurality of covering units arranged in an array is provided. Next, a plurality of light guiding mediums are formed over the cover plate. Next, the cover plate is bonded with the wafer by an adhesive, wherein each of the covering units covers and bonds with one of the chips, and the light guiding mediums are sandwiched between the cover plate and the wafer. Then, the wafer and the cover plate are diced to obtain the plurality of photoelectric modules.

Abstract: Occurrence of a void is suppressed when mounting semiconductor chips over a wiring substrate via a paste-like adhesive material. A die bonding step is provided which mounts semiconductor chips over a chip-mounting region of the wiring substrate via the adhesive material. The wiring substrate includes a plurality of wirings (first wirings) and dummy wirings (second wirings) formed on an upper surface of a core layer. The chip-mounting region is provided over the first wirings and the second wirings. In addition, the die bonding step includes a step of applying the adhesive material over an adhesive material application region over the chip-mounting region. Each of the second wirings is extended along a direction in which the adhesive material spreads in the die bonding step.

Abstract: A semiconductor package includes: a semiconductor element mounted on a one-sided plane of a wiring board; an underfill agent dropped so as to be filled between the semiconductor element and the wiring board; and a pad group constituted by a plurality of pads which are formed in the vicinity of a circumference of the wiring board and along the circumference, the pad group being formed on a bottom plane of a groove portion formed in a solder resist which covers the one-sided plane of the wiring board, wherein a corner edge of the groove portion located in the vicinity of a dropping starting portion to which dropping of the underfill agent is started is formed at an obtuse angle or in an arc shape in order to avoid the dropped underfill agent from entering into an inner portion of the groove portion.

Abstract: A semiconductor device includes a semiconductor chip, an electrode pad formed on the semiconductor chip, an underlying barrier metal formed on the electrode pad, a solder bump formed on the underlying barrier metal, and an underfill material surrounding the underlying barrier metal and the solder bump. A junction interface of the solder bump with the underlying barrier metal corresponds to an upper surface of the underlying barrier metal, and a portion of the underfill material bonded to a side surface of the solder bump and an end surface of the underlying barrier metal forms a right angle or an obtuse angle.

Abstract: Even when a stiffener is omitted, the semiconductor device which can prevent the generation of twist and distortion of a wiring substrate is obtained. As for a semiconductor device which has a wiring substrate, a semiconductor chip by which the flip chip bond was made to the wiring substrate, and a heat spreader adhered to the back surface of the semiconductor chip, and which omitted the stiffener for reinforcing a wiring substrate and maintaining the surface smoothness of a heat spreader, a wiring substrate has a plurality of insulating substrates in which a through hole whose diameter differs, respectively was formed, and each insulating substrate contains a glass cloth.

Abstract: Disclosed herein are a power package module and a method for fabricating the same, including: a base substrate; a plurality of high power chips and a plurality of low power chips electrically connected to the base substrate; and a plurality of metal lead plates electrically connecting the plurality of high power chips and the plurality of low power chips to the base substrate.

Abstract: A chip assembly includes a PCB, a connecting pad fixed on the PCB, and a chip. The connecting pad defines a through hole. The chip is received in the through hole and fixed on the PCB by an adhesive distributed in the through hole. A thickness of the adhesive is less than that of the connecting pad.

Abstract: A method for attaching a metal surface to a carrier is provided, the method including: depositing a porous layer over at least one of a metal surface and a side of a carrier; and attaching the at least one of a metal surface and a side of a carrier to the porous layer by bringing a material into pores of the porous layer, resulting in the material forming an interconnection between the metal surface and the carrier.

Abstract: Embodiments provide a method of forming a chip package. The method may include attaching at least one chip on a carrier, the chip including a plurality of chip pads on a surface of the chip opposite to the carrier; depositing a first adhesion layer on the carrier and on the chip pads of the chip, the first adhesion layer including tin or indium; depositing a second adhesion layer on the first adhesion layer, the second adhesion layer including a silane organic material; and depositing a lamination layer or an encapsulation layer on the second adhesion layer and the chip.

Abstract: A chip package includes a PCB, a connecting pad fixed on a surface of the PCB and a chip fixed on the connecting pad. The connecting pad includes a first metal film on its surface facing away from the PCB. The chip includes a second metal film formed on its surface opposite to the PCB. The first and the second metal are connected to each other via a eutectic manner.

Abstract: A semiconductor device has a semiconductor die with a plurality of composite bumps formed over a surface of the semiconductor die. The composite bumps have a fusible portion and non-fusible portion, such as a conductive pillar and bump formed over the conductive pillar. The composite bumps can also be tapered. Conductive traces are formed over a substrate with interconnect sites having edges parallel to the conductive trace from a plan view for increasing escape routing density. The interconnect site can have a width less than 1.2 times a width of the conductive trace. The composite bumps are wider than the interconnect sites. The fusible portion of the composite bumps is bonded to the interconnect sites so that the fusible portion covers a top surface and side surface of the interconnect sites. An encapsulant is deposited around the composite bumps between the semiconductor die and substrate.

Abstract: The present invention relates to a method of making a cavity substrate. In accordance with a preferred embodiment, the method includes: preparing a supporting board including a stiffener, a bump/flange sacrificial carrier and an adhesive, wherein the adhesive bonds the stiffener to the sacrificial carrier; forming a coreless build-up circuitry on the supporting board in contact with the bump and the stiffener; and removing the bump and a portion of the flange to form a cavity and expose a conductive via of the coreless build-up circuitry from a closed end of the cavity, wherein the cavity is laterally covered and surrounded by the adhesive. A semiconductor device can be mounted on the cavity substrate and electrically connected to the conductive via. The coreless build-up circuitry provides signal routing for the semiconductor device while the stiffener can provide adequate mechanical support for the coreless build-up circuitry and the semiconductor device.

Abstract: A method for producing a semiconductor chip laminate, which comprises applying an adhesive to a substrate or other semiconductor chip; laminating the semiconductor chip on the substrate or other semiconductor chip via the adhesive; uniformly wetting and spreading the adhesive on an entire region for bonding the semiconductor chip on the substrate or other semiconductor chip; and curing the adhesive. In the application step, an area for applying adhesive is 40% to 90% of the region for bonding the semiconductor chip located on the substrate or other semiconductor chip, immediately after laminating, an area with the adhesive thereon is 60% to less than 100% of the region for bonding the semiconductor chip on the substrate or other semiconductor chip, and in wetting and spreading the adhesive, a viscosity of adhesive between the substrate or other semiconductor chips and the semiconductor chip at 0.5 rpm is 1 Pas to 30 Pas.

Abstract: A fabricating method of a semiconductor package structure is provided. A dielectric layer having a first surface and a second surface is provided. A patterned metal layer has been formed on the first surface of the dielectric layer. An opening going through the first and the second surfaces is formed. A carrier having a third surface and a fourth surface is formed at the second surface. A portion of the third surface is exposed by the opening of the dielectric layer. A semiconductor die having a joining surface and a side-surface is joined in the opening. At least a through hole going through the third and the fourth surfaces is formed. A metal layer having at least a heat conductive post extending from the fourth surface of the carrier to the through hole and disposed in the through hole and a containing cavity is formed on the fourth surface.

Abstract: A back of a dielectric transparent handle substrate is coated with a blanket conductive film or a mesh of conductive wires. A semiconductor substrate is attached to the transparent handle substrate employing an adhesive layer. The semiconductor substrate is thinned in the bonded structure to form a stack of the transparent handle substrate and the semiconductor interposer. The thinned bonded structure may be loaded into a processing chamber and electrostatically chucked employing the blanket conductive film or the mesh of conductive wires. The semiconductor interposer may be bonded to a semiconductor chip or a packaging substrate employing C4 bonding or intermetallic alloy bonding. Illumination of ultraviolet radiation to the adhesive layer is enabled, for example, by removal of the blanket conductive film or through the mesh so that the transparent handle substrate may be detached. The semiconductor interposer may then be bonded to a packaging substrate or a semiconductor chip.

Abstract: Provided is a method of fabricating an image sensor device. The method includes providing a first substrate having a radiation-sensing region disposed therein. The method includes providing a second substrate having a hydrogen implant layer, the hydrogen implant layer dividing the second substrate into a first portion and a second portion. The method includes bonding the first portion of the second substrate to the first substrate. The method includes after the bonding, removing the second portion of the second substrate. The method includes after the removing, forming one or more microelectronic devices in the first portion of the second substrate. The method includes forming an interconnect structure over the first portion of the second substrate, the interconnect structure containing interconnect features that are electrically coupled to the microelectronic devices.

Abstract: A method of attaching a die to a substrate is disclosed. A major surface of the die has an array of electrical contacts, and is covered with a tape segment having an array of apertures in register with the contacts. Solder balls are inserted into the apertures. The die is positioned against a substrate with the solder balls in register with the die pads on the surface of the substrate, and a heat treatment process is performed to bond the conductive elements to the corresponding bond pads.

Abstract: A method for manufacturing an optoelectronic apparatus includes attaching bottom surfaces of first and second packaged optoelectronic semiconductor devices (POSDs) to a carrier substrate (e.g., a tape) so that there is a space between the first and second POSDs. An opaque molding compound is molded around portions of the first and second POSDs attached to the carrier substrate, so that peripheral surfaces of the first POSD and the second POSD are surrounded by the opaque molding compound, the space between the first and second POSDs is filled with the opaque molding compound, and the first and second POSDs are attached to one another by the opaque molding compound. The carrier substrate is thereafter removed so that electrical contacts on the bottom surfaces of the first and second POSDs are exposed. A window for each of the POSDs is formed during the molding process or thereafter.