Abstract: Methods and systems of applying a plurality of pieces of die attach film to a plurality of singulated dice are provided. The method can involve making intervals between rows and columns of a plurality of pieces of die attach film. The interval can be made by expanding an underlaid expandable film on which the plurality of pieces of die attach film are placed or by removing portions of the die attach film between rows and columns of the plurality of pieces of die attach film. The method can further involve placing a plurality of singulated dice back side down on the plurality of pieces of die attach film.

Abstract: An LED assembly includes a heat sink and a submount. The heat sink has a top mating surface that is solder wettable, and the submount has a bottom mating surface that is solder wettable. The top and the bottom mating surfaces have substantially the same shape and area. The submount is soldered atop the heat sink. During solder reflow, the molten solder causes the submount to align with the top mating surface of the heat sink. The LED assembly may further include a substrate having a top mating surface, and the heat sink may further include a bottom mating surface. The top and bottom mating surfaces have substantially the same shape and area. The heat sink is soldered atop the substrate. During solder reflow, the molten solder causes the heat sink to align with the top mating surface of the substrate.

Abstract: An LED and light guide assembly has an LED with an output surface; a first power input lead electrically coupled to a first pole and having a first surface and a second surface; and a second power input lead electrically coupled to a second pole and having a first surface and a second surface. A unitary, molded light guide has an axially extending, light transmissive body with a light output window. An input window is formed with the unitary, molded light guide being aligned in a zero-gap relationship to capture substantially all the light emitted by the LED. A support is formed integral with the light guide and envelopes a portion of the first surface and the second surface of the first power input lead and the first surface and the second surface of the second power input lead to anchor the guide with respect to the power inputs.

Abstract: An optical device includes an optical element, a transparent member arranged on the optical element, and a transparent resin adhesive for causing the transparent member to adhere and be fixed onto a circuit formation face of the optical element. The optical device includes a light detecting region having a plurality of micro lenses, a peripheral circuit region formed in the outer peripheral part of the light detecting region, and an electrode region formed at the outer peripheral part of the peripheral circuit region. A roughed region in a saw-toothed shape in section is formed in part of a face of the transparent member which adheres to the optical element, the part being overlapped with the outer peripheral part of the light detecting region as viewed in plan.

Abstract: The present invention relates to affixing components of optical packages. The optical packages can include an optical component, such as a TO-Can. The TO-Can can house an optical transmitter and/or an optical receiver. Another optical component of the optical package can be a barrel for aligning the TO-Can with an optical fiber. The TO-Can can be affixed within an open end of the optical barrel using a bonding substance, such as an epoxy, that has wicking properties. The wicking properties cause the bonding substance to enter a gap between the optical barrel and the TO-Can by capillary action. Use of the bonding substance with wicking properties creates a more robust optical package in a cost effective manner.

Abstract: A method is disclosed for making a leadframe package stand having application in semiconductor packaging and microelectronic assembly in which an IC device (e.g., a bare chip IC, a wafer level package, or a chipscale package) is received for electrical connection to a PWB or for vertical package over package stacking. Electrically conductive leadframe traces are arranged in an area array circuit pattern between outer leads at the periphery of the mold body of a leadframe for connection to the PWB to inner leads for connection to the IC device. The inner lead tips terminate at each side of the IC device in groups of parallel aligned rows and columns to facilitate connection to the IC device without using intermediate bonding wires. Prior to molding, the inner leads of the conductive traces are secured by sacrificial tie-bars or adhesive tape to prevent movement of the inner leads and possible short circuits during molding. A cavity is formed in the mold body during molding so as to lie above the inner leads.

Abstract: A method of self-assembly of components on a surface of a substrate includes obtaining a first component and a second component. The first component type is assembled onto the substrate by programming the surface. The second component type is assembled by reprogramming the surface. A third component, next to the first and second components, is assembled following the step of assembling the first and second components. The first, second, and third components are all different types of components. docking sites on the substrate can be used that contain alignment pedestals. One component delivery system employ a liquid-liquid interface to deliver and concentrate components with correct pre-orientation.

Abstract: An image sensing device and a packaging method thereof is disclosed. The packaging method includes the steps of providing an adhesive layer; placing a substrate, having an opening, on the adhesive layer; disposing an image sensor within the opening on the adhesive layer; adding a filler between the image sensor and the substrate; connecting the image sensor and the substrate via a plurality of bonding wires; and removing the adhesive layer.

Abstract: An improved imaging device having a pixel arrangement featuring a multilayer light shield. The multilayer light shield includes stacked layers of light-shielding and light-transparent material. The light-transparent material, such as a dielectric, is selected to have a stress, such as a tensile stress, that offsets the stress, such as a compressive stress, of the light shielding material. Without the stress offset, the high compressive stress of the refractory metal could damage the integrity of the nearby silicon. The refractory metal is capable of withstanding the high temperatures associated with front end CMOS processing. The laminate structure allows the light shield to be placed close to the pixel surface. The light-transparent material has a thickness equal to about one-quarter wavelength of the light to be blocked, to act as an anti-reflective coating. An aperture in the light shield exposes the active region of the pixel's photoconversion device.

Abstract: According to one embodiment, a micro-optical device includes an electro-optical circuit and an annular frame disposed on a surface of a substrate. The electro-optical circuit has an active region that is encapsulated by a window and an interconnect region adjacent at least one edge of the electro-optical circuit. The annular frame extends around an outer periphery of the window and is separated from the window by a gap, the annular frame and the electro-optical circuit form a cavity for placement of a plurality of bonding wires the interconnect that electro-optical circuit to the substrate.

Abstract: A method of manufacturing a light emitting display including an image display part formed on a substrate and a pad part including at least one terminal electrically connected to the image display part. The method includes forming thin film transistors and at least one electroluminescent device electrically connected to the thin film transistors and including a first electrode layer, an emission layer, and a second electrode layer on the image display part, forming a protection layer on the second electrode layer of the electroluminescent device and the pad part, sealing the image display part on the protection layer, and removing the protection layer formed at least on the pad part to expose the terminals. Therefore, it is possible to easily remove the protection layer formed of organic material or inorganic material formed on the pad part without an additional mask.

Abstract: An optical sensor package that includes an optical sensor die is mounted by flip chip interconnect onto a lead frame in a “die-down” orientation, that is, with the active side of the optical sensor die facing the lead frame. An opening is provided in the lead frame die paddle (pad), and light passes from outside the package through the opening in the lead frame die pad onto light collection elements on the active side of the chip.

Abstract: Embodiments relate to a CMOS image sensor and to a method for manufacturing a CMOS image sensor that may disperse stray beam between microlenses. According to embodiments, the method for manufacturing the CMOS image may include forming an interlayer dielectric layer on a semiconductor substrate including a plurality of photo diodes, forming a color filter layer corresponding to the photo diodes on the interlayer dielectric layer, forming a planarization layer on the color filter layer, forming microlenses on the planarization layer, after depositing an insulating layer over the microlenses, forming a trench in a concave lens shape in the insulating layer between the microlenses, and forming a concave lens gap-filling insulating materials inside the trench. In embodiments, concave lenses may be formed between microlenses in a CMOS image sensor and stray beams between the microlenses may be dispersed and recondensed into the microlenses.

Abstract: A mounted body (100) of the present invention includes: a semiconductor element (10) having a surface (10a) on which element electrodes (12) are formed and a rear surface (10b) opposing the surface (10a); and a mounting board (30) on which wiring patterns (35) each having an electrode terminal (32) are formed. The rear surface (10b) of the semiconductor element (10) is in contact with the mounting board (30), and the element electrodes (12) of the semiconductor element (10) are connected electrically to the electrode terminals (32) of the wiring pattern (35) formed on the mounting board (30) via solder connectors (20) formed of solder particles assembled into a bridge shape. With this configuration, fine pitch connection between the element electrodes of the semiconductor element and the electrode terminals of the mounting board becomes possible.

Abstract: A semiconductor device manufacturing method can produce semiconductor light emitting/detecting devices that have high connective strength and high luminous energy by increasing contact areas of electrodes thereof and decreasing enclosed areas of electrodes thereof. A wafer is provided with a semiconductor substrate and a semiconductor epitaxial layer. A plurality of substrate concave portions and epitaxial layer concave portions are formed on the semiconductor substrate and the semiconductor epitaxial layer, respectively. Substrate electrodes and epitaxial layer electrodes are formed in the substrate concave portions and the epitaxial layer concave portions. A substrate surface electrode and an epitaxial layer surface electrode can be formed on the semiconductor substrate and the substrate electrodes and the semiconductor epitaxial layer and the epitaxial layer electrodes, respectively.

Abstract: In a printed circuit board, a semiconductor including plural power supply terminals and a semiconductor chip is mounted onto a mounting surface of a printed wiring board, and a bypass capacitor for reducting a power ground noise is provided. Another bypass capacitor, which is connected to the bypass capacitor only within an IC chip is provided to inhibit the power ground noise from causing not only a variation in timing of the IC chip and a malfunction thereof but also a malfunction of another IC chip and the generation of an EMI noise in a case where the power ground noise propagates to a power supply side.

Abstract: A solid-state imaging device comprises a housing in which a base and ribs forming a rectangular frame are formed in one piece by a resin; a plurality of metal lead pieces embedded in the housing, each of which has an internal terminal portion facing an internal space of the housing and an external terminal portion exposed at an outer portion of the housing; an imaging element arranged on the base in the internal space of the housing; connecting members connecting electrodes of the imaging element to the internal terminal portions of the metal lead pieces; and a transparent plate fastened to an upper face of the ribs. The upper face of the ribs is provided with a lower step portion that is lowered along an external periphery, and the transparent plate is fastened to the upper face of the ribs by an adhesive filled at least into the lower step portion.

Abstract: In a method of manufacturing an optical device, a whole substrate is first prepared which has a plurality of regions corresponding to substrates constituting a plurality of optical devices, respectively. A plurality of chips are then mounted to the plurality of regions, respectively. A whole sealing member having a plurality of sealing members is integrally attached to the whole substrate to form an intermediate body. The intermediate body is divided into the above-described regions. Thus, the optical device having a substrate, a chip as an optical element mounted to the substrate and a sealing member with transparency provided at the substrate for the purpose of sealing the chip is manufactured. This manufacturing method improves the efficiency of manufacturing an optical device.

Abstract: Methods of forming LED packages and light emitting devices are provided. LED packages and light emitting devices are preferably formed from ceramic layers, such as AlN, though layers of non-ceramic materials can also be used. The layers are formed to include vias, apertures, and metallization layers. The layers are then bonded together to form a panel. The panel is scribed to form a grid of snap lines and then the panel is fractured along the snap lines. To form light emitting devices from the panel, LED dies are added and encapsulated before the panel is fractured.

Abstract: A packaging structure suitable for an integrated circuit device receiving short-wavelength laser light is provided. A lead-mounted substrate is placed on the side of the light receiving surface of the integrated circuit device having a photo detecting part. The lead is electrically connected with the integrated circuit device via an electrode. The integrated circuit device and the substrate are encapsulated with an encapsulation section. The substrate has an opening at a position above the photo detecting part.

Abstract: Methods for manufacturing microelectronic imaging units and microelectronic imaging units that are formed using such methods are disclosed herein. In one embodiment, a method includes coupling a plurality of singulated imaging dies to a support member. The individual imaging dies include an image sensor, an integrated circuit operably coupled to the image sensor, and a plurality of external contacts operably coupled to the integrated circuit. The method further includes forming a plurality of stand-offs on corresponding imaging dies before and/or after the imaging dies are singulated and electrically connecting the external contacts of the imaging dies to corresponding terminals on the support member. The individual stand-offs include a portion between adjacent external contacts.

Abstract: The invention relates to a method for the manufacture of packaged components. The invention is based here on the problem of facilitating the application of covers with lateral dimensions that are smaller than the lateral dimensions of the functional substrate. For this purpose, a plate-like cover substrate is mounted on a carrier substrate. Then, on the uncovered side of the plate-like cover substrate, trenches are inserted, so that a composite part is obtained with the carrier substrate and individual covering parts that are separated from each other by the trenches, but interconnected by the carrier substrate. The covering parts of the composite part are connected with a functional substrate with a plurality of components. Then, the connection of the covering parts is dissolved with the carrier substrate, and the carrier substrate is removed, so that a composite is obtained with the functional substrate and a plurality of covering parts that cover functional areas.

Abstract: A semiconductor element is mounted on a rectangular base of a package including the base and ribs provided on a pair of opposite external edges of the base. Electrode pads of the semiconductor element and connection electrodes provided on rib upper surfaces are connected to each other by metal wires. On the rib upper surfaces, spacers are provided at locations closer to the outside than the connection electrodes. A transparent lid adheres to the upper surfaces of the spacers to cover the entire surface of the package. The height of the spacers is greater than the diameter of the metal wires.

Abstract: A semiconductor package such as an image sensor package, and methods for fabrication. A frame structure includes an array of frames, each having an aperture therethrough, into which an image sensor die in combination with a cover glass, filter, lens or other components may be installed in precise mutual alignment. Singulated image sensor dice and other components may be picked and placed into each frame of the frame structure. Alternatively, the frame structure may be configured to be aligned with and joined to a wafer bearing a plurality of image sensor dice, wherein optional, downwardly protruding skirts along peripheries of the frames may be received into kerfs cut along streets between die locations on the wafer, followed by installation of other package components. In either instance, the frame structure in combination with singulated image sensor dice or a joined wafer is singulated into individual image sensor packages. Various external connection approaches may be used for the packages.

Abstract: The present invention provides flip-chip packaging for optically interactive devices such as image sensors and methods of assembly. In a first embodiment of the invention, conductive traces are formed directly on the second surface of a transparent substrate and an image sensor chip is bonded to the conductive traces. Discrete conductive elements are attached to the conductive traces and extend below a back surface of the image sensor chip. In a second embodiment, a secondary substrate having conductive traces formed thereon is secured to the transparent substrate. In a third embodiment, a backing cap having a full array of attachment pads is attached to the transparent substrate of the first embodiment or the secondary substrate of the second embodiment. In a fourth embodiment, the secondary substrate is a flex circuit having a mounting portion secured to the second surface of the transparent substrate and a backing portion bent over adjacent to the back surface of the image sensor chip.

Abstract: There is provided a method for manufacturing a display device. The method includes the steps of: forming a bottom electrode for supplying a first charge, in individual pixels on a substrate; forming a pattern of a first light-emitting layer having a first-charge transport property above the bottom electrode in part of the pixels; subjecting the substrate having the first light-emitting layer formed thereon to heat treatment; forming a pattern of a second light-emitting layer having a second-charge transport property on the heat-treated surface above the bottom electrode in the other pixels; and forming a top electrode for supplying a second charge so that the first light-emitting layer and the second light-emitting layer are sandwiched between the bottom electrode and the top electrode.

Abstract: Microelectronic imaging devices and methods of packaging microelectronic imaging devices are disclosed herein. In one embodiment, the microelectronic imaging devices include an interposer substrate and a plurality of imager units coupled to the interposer substrate. The interposer substrate includes a plurality of openings and a plurality of contact arrays proximate to corresponding openings. The individual imager units include a microelectronic die with an image sensor and a plurality of bond-pads electrically coupled to the image sensor. The image sensors are aligned with corresponding openings on the interposer substrate, and the bond-pads are electrically coupled to corresponding contacts on the interposer substrate.

Abstract: Self-assembly of components carried in a fluid is provided. A first component and a second component are obtained and self-assembled together. A third component is obtained and assembled with the first and second components, following the step of assembling the first and second components. The first, second and third components are all different types of components.

Abstract: To provide a manufacturing method of a semiconductor device with a reduced chip area by reducing the size of a pattern for forming an integrated circuit. For example, the size of an IC chip that is provided as an application of IC cards or IC tags can be reduced. The manufacturing method includes the steps of forming a gate electrode; forming an insulating layer over the gate electrode; and forming an opening in the insulating layer. One or both of the step of forming the gate electrode and the step of forming the opening in the insulating layer is/are conducted by a lithography process using a phase-shift mask or a hologram mask. Accordingly, micropatterns can be formed even over a substrate with low planarity such as a glass substrate.

Abstract: An image capturing device is disclosed that includes a light receiving element having a light receiving surface, a plate-like transparent member provided on the light receiving surface of the light receiving element, and resin provided to at least the periphery of the plate-like transparent member. The plate-like transparent member includes a first principal plane positioned on the light receiving element side and a second principal plane opposite the first principal plane. The first principal plane is greater in area than the second principal plane.

Abstract: With this semiconductor device, the distortion and cracking of a thinned portion of a semiconductor substrate are prevented to enable high precision focusing with respect to a photodetecting unit and uniformity and stability of high sensitivity of the photodetecting unit to be maintained. A semiconductor device 1 has a semiconductor substrate 10, a wiring substrate 20, conductive bumps 30, and a resin 32. A CCD 12 and a thinned portion 14 are formed on semiconductor substrate 10. Electrodes 16 of semiconductor substrate 10 are connected via conductive bumps 30 to electrodes 22 of wiring substrate 20. Wiring substrate 20 is subject to a wettability processing by which a region 26a that surrounds a region opposing thinned portion 14 and regions 26b that extend to the outer side from region 26a are lowered in the wettability with respect to the resin.

Abstract: With this semiconductor device, the distortion and cracking of a thinned portion of a semiconductor substrate are prevented to enable high precision focusing with respect to a photodetecting unit and uniformity and stability of high sensitivity of the photodetecting unit to be maintained. A semiconductor device 1 has a semiconductor substrate 10, a wiring substrate 20, conductive bumps 30, and a resin 32. A CCD 12 and a thinned portion 14 are formed on semiconductor substrate 10. Electrodes 16 of semiconductor substrate 10 are connected via conductive bumps 30 to electrodes 22 of wiring substrate 20. Wiring substrate 20 has formed therein a groove portion 26a that surrounds a region opposing thinned portion 14 and groove portions 26b that extend to an exposed surface of wiring substrate 20 from groove portion 26a. Insulating resin 32 fills a gap between outer edge 15 of thinned portion 14 and wiring substrate 20 to reinforce the bonding strengths of conductive bumps 30.

Abstract: In a camera module (1) of the present invention, a lens member (20) is attached to a semiconductor package (10). The semiconductor package (10) includes: an image sensor (11) mounted on a wiring board (13); and a wire 15 through which the wiring board (13) is electrically connected to the image sensor (11). The image sensor (11) and the wire 15 are sealed with mold resin (14). A step (18) is formed around the perimeter of the surface of the mold resin (14), and the semiconductor package (10) and the lens member (20) are joined by fitting the step (18) and a projection (23) of a lens holder (22). With this arrangement, it is possible to realize a small semiconductor module that allows for highly precise alignment between the semiconductor package and a mounting component to which the semiconductor package is joined.

Abstract: A cap wafer with cavities is etched through areas not covered by a patterned photoresist to form a plurality of openings. The cap wafer is bonded to a transparent wafer at the surface having the cavities and is segmented around the cavities to form a plurality of cap structures. The cap structures are hermetically sealed to a device wafer to form hermetic windows over devices and pads located on the device wafer.

Abstract: System and method for preventing resin-based adhesive from contacting a substrate to minimize resin bleed-out and contamination. A preferred embodiment comprises a semiconductor device having a die mounted on a substrate, first and second gold surfaces formed on the substrate, a trench formed between the first and second gold surfaces, resin-based adhesive applied to the first gold surface, and a heat sink bonded to the resin-based adhesive.

Abstract: The invention provides an image sensor package and method for fabricating the same. The image sensor package comprises a first substrate comprising a sensor device thereon and a hole therein. A bonding pad comprising a first opening is formed on an upper surface of the first substrate. A second substrate comprising a spacer element with a second opening therein is disposed on the first substrate. A conductive plug is formed in the hole and passes through the first and second openings to the second substrate to electrically contact with the bonding pad. A conductive layer is formed on a lower surface of the first substrate and electrically connects to the conductive plug. A solder ball is formed on the conductive layer and electrically connects to the bonding pad by the conductive plug. The image sensor package further comprises a second substrate bonding to the first substrate. The image sensor package is relatively less thick, thus, the dimensions thereof are relatively reduced.

Abstract: A semiconductor device is made by providing a semiconductor die having an optically active area, providing a leadframe or pre-molded laminated substrate having a plurality of contact pads and a light transmitting material disposed between the contact pads, attaching the semiconductor die to the leadframe so that the optically active area is aligned with the light transmitting material to provide a light transmission path to the optically active area, and disposing an underfill material between the semiconductor die and leadframe. The light transmitting material includes an elevated area to prevent the underfill material from blocking the light transmission path. The elevated area includes a dam surrounding the light transmission path, an adhesive ring, or the light transmission path itself can be the elevated area. An adhesive ring can be disposed on the dam. A filler material can be disposed between the light transmitting material and contact pads.

Abstract: A semiconductor package board for mounting thereon a semiconductor chip includes a metal base having an opening for receiving therein the semiconductor chip and a multilayer wiring film layered onto the metal base. The semiconductor chip is flip-chip bonded onto the metal pads disposed on the multilayer wiring film within the opening. The surface of the metal base is flush with the top surface of the semiconductor chip received in the opening. The resultant semiconductor device has a larger number of external pins and a smaller deformation without using a stiffener.

Abstract: The MEMS package has a mounting substrate on which one or more transducer chips are mounted wherein the mounting substrate has an opening. A top cover is attached to and separated from the mounting substrate by a spacer forming a housing enclosed by the top cover, the spacer, and the mounting substrate and accessed by the opening. Electrical connections are made between the one or more transducer chips and the mounting substrate and/or between the one or more transducer chips and the top cover. A bottom cover can be mounted on a bottom surface of the mounting substrate wherein a hollow chamber is formed between the mounting substrate and the bottom cover, wherein a second opening in the bottom cover is not aligned with the first opening. Pads on outside surfaces of the top and bottom covers can be used for further attachment to printed circuit boards. The top and bottom covers can be a flexible printed circuit board folded under the mounting substrate.

Abstract: A method of manufacturing an infrared rays receiver comprises the steps of: chip attach; wire bonding; encapsulation; metal housing covering; encapsulation; pin cutting; and testing. A lead frame has several pins, wherein one pin has a coupling part. An infrared rays receiving chip is coupled to the coupling part of the pin of the lead frame, and electrically connected to the other pins by bonding wires. Thereafter, a light-pervious adhesive encapsulates part of the lead frame, the chip, and the bonding wires. Thereafter, the light-pervious adhesive is covered with a metal housing having a through hole so as to expose the infrared rays receiving chip via the through hole. Thereafter, the metal housing and the light-pervious adhesive are encapsulated into a unity by a colored adhesive. Consequently, the infrared rays receiver is protected from the occurrence of short circuits and has a metal shielding effect to provide a longer transmission distance.

Abstract: A conducting layer in a chip package module includes one or a plurality of through hole penetrating the top of a base being disposed at the bottom of an insulating layer in the chip package module, and inner wall of the through hole being applied with insulation material so that the conductive layer subsequently constructed to the peripheral of the insulation layer may pass the through hole to extend to where above the base before construction of a masking layer and multiple circuit pins to complete construction of the conducting layer that is totally enveloped so to prevent easy oxidization at the conducting layer and improve stability of the chip package to avoid breaking up due to external force applied.

Abstract: This invention relates to a packaging structure and method of an image sensor module. The method comprises: providing a transparent substrate having a first patterned conductive layer; carrying an image sensor integrated circuit chip having a photosensitive active area and at least one passive chip on the transparent substrate, wherein the photosensitive active area faces the transparent substrate; forming an insulating build-up film over the transparent substrate; and forming a plurality of conductive vias in the insulating build-up film wherein the ends of the conductive vias are connected with the passive chip or the first patterned conductive layer of the transparent substrate while the other ends of the conductive vias are exposed on the surface of the insulating build-up film. The packaging method is capable of down-sizing the construction of the image sensor module and simplifying the processing steps.

Abstract: A method of forming a wall structure in a microelectronic assembly includes selectively depositing a flowable material on an upper surface of a first element in the microelectronic assembly, positioning a molding surface in contact with the deposited flowable material and controlling a distance between the upper surface of the first element and the molding surface with one or more objects positioned between the upper surface and the molding surface.

Abstract: A method according to the present invention for producing a semiconductor-chip-mounting circuit 1 includes mainly three steps. In a first step, contacts 2 each in the form of a conical helix are formed by solder-plating the surface of connecting terminals 12 on a mounting circuit 10. In a second step, a continuity test is performed by pressing bumps 21 against the contacts 2. In a final third step, the contacts 2 pressed are melted to connect the connecting terminals 12 to the bumps 21. That is, the semiconductor chip 20 is connected to the mounting circuit 10 while maintaining a state in which they pass the continuity test, thereby significantly reducing the occurrence of defective continuity in the semiconductor-chip-mounting circuit 1.

Abstract: One embodiment relates to an optical navigation device. The device includes a lead frame having reference features, a laser, a detector array, and an optical component having alignment features. The laser is attached to the lead frame and positioned in reference to the reference features of the lead frame. The detector array is attached to the lead frame and positioned in reference to the reference features of the lead frame. The optical component is coupled to the lead frame so that its alignment features register to the reference features of the lead frame. In this way, the molded optical component is passively aligned to the laser and the detector array. Other embodiments are also disclosed.

Abstract: To provide a semiconductor device 10, which is thin, compact, and excellent in mechanical strength and humidity resistance. Semiconductor device 10A has a configuration such that in semiconductor device 10A, wherein an optical semiconductor element 14, having a light receiving part or a light emitting part, is sealed in a sealing resin 13, a cover layer 12, covering the top surface of optical semiconductor element 14, is exposed from the top surface of sealing resin 13. Thus in comparison to a related-art example with which the entirety is sealed by a transparent resin, sealing resin 13 can be formed thinly and the thickness of the entire device can be made thin. Furthermore, semiconductor device 10 is arranged using a sealing resin having a filler mixed in. A semiconductor device that is excellent in mechanical strength and humidity resistance can thus be arranged.

Abstract: An optical device includes a base, an optical element chip attached to the base, an integrated circuit chip attached onto the back surface of the optical element chip, and a translucent member (window member). A wire is buried within the base, and the wire has an internal terminal portion, an external terminal portion, and a midpoint terminal portion. A pad electrode of the optical element chip is connected to the internal terminal portion through a bump, and a pad electrode of the integrated circuit chip is connected to the midpoint terminal portion through a fine metal wire.

Abstract: This invention provides a sensor semiconductor package and a method for fabricating the same. The method includes: mounting on a substrate a sensor chip having a sensor area; electrically connecting the sensor chip and the substrate by means of bonding wires; forming on a transparent member an adhesive layer with an opening corresponding in position to the sensor area; and mounting the transparent member on the substrate via the adhesive layer while heating the substrate, such that the adhesive layer melts, to thereby encapsulate the periphery of the sensor chip and the bonding wires while exposing the sensor area from the adhesive layer. Thus, the sensor area is sealed by the transparent member cooperative with the adhesive layer, making the sensor semiconductor package thus-obtained dam-free, light, thin, and compact, and incurs low process costs. Also, the product reliability is enhanced since the bonding wires are encapsulated by the adhesive layer without severing concern.

Abstract: A chip package including a package substrate, a chip, several bonding wires, a flash-resisting ring and a molding compound. The package substrate includes a carrying surface and several contacts disposed on the carrying surface. The chip is disposed on the carrying surface. A surface of the chip away from the package substrate includes an active region and several bonding pads. The bonding pads are located outside the active region. The bonding wires connect the bonding pads and the contacts. The flash-resisting ring disposed on the chip is located between the bonding pads and the active region. The flash-resisting ring surrounding the active region includes at least one buffer groove. The buffer groove surrounds the active region. The molding compound disposed on the package substrate and the chip encapsulates at least the bonding pads, the contacts and the bonding wires. The molding compound exposes the active region.

Abstract: A packaged circuit and method for packaging an integrated circuit are disclosed. The packaged circuit has a lead frame, an integrated circuit chip, and an encapsulating layer. The lead frame has first and second sections, the first section including a lateral portion, a chip mounting area and a first extension. The integrated circuit chip is mounted in the chip mounting area and is in thermal contact with the chip mounting area. The encapsulating layer has top, bottom, and first and second side surfaces. The first extension is bent to provide a first heat path from the chip mounting area to the bottom surface. The heat path connects the heat chip mounting area to the bottom surface without passing through the first and second side surfaces and provides a heat path that has less thermal resistance than the heat path through either the lateral portion or the second section.