Abstract: An optoelectronic apparatus includes one or more packaged optoelectronic semiconductor devices (POSDs), each including one or more optoelectronic elements encapsulated by a light transmissive molding compound. Each POSD includes a top surface formed by a top surface of the light transmissive molding compound that encapsulates the one or more optoelectronic elements of the POSD. Each POSD also includes a bottom surface including electrical contacts for the one or more optoelectronic elements of the POSD. A peripheral surface extends between the top and bottom surfaces. A light reflective molding compound surrounds the peripheral surface of each POSD and forms a reflector cup for each POSD. The electrical contacts on the bottom surface of each POSD are exposed, and thus, are accessible for electrical connections to other circuitry. Where the optoelectronic apparatus includes a plurality of POSDs, the light reflective molding compound also connects neighboring POSDs to one another.

Abstract: Packaged light detector semiconductor devices (PLDSDs), methods for manufacturing PLDSDs, and systems including a PLDSD are described herein. In an embodiment, a PLDSD includes a light detector die having a surface including an active photosensor region, and a non-imaging optical concentrator including an entrance aperture and an exit aperture axially aligned with one another and with the active photosensor region. A molding material forms the non-imaging optical concentrator and encapsulates at least a portion of the surface of the light detector die that extends beyond the exit aperture of the non-imaging optical concentrator. The non-imaging optical concentrator concentrates light from the entrance aperture toward the exit aperture and onto the active photosensor region.

Abstract: An optoelectronic apparatus includes one or more packaged optoelectronic semiconductor devices (POSDs), each including one or more optoelectronic elements encapsulated by a light transmissive molding compound. Each POSD includes a top surface formed by a top surface of the light transmissive molding compound that encapsulates the one or more optoelectronic elements of the POSD. Each POSD also includes a bottom surface including electrical contacts for the one or more optoelectronic elements of the POSD. A peripheral surface extends between the top and bottom surfaces. A light reflective molding compound surrounds the peripheral surface of each POSD and forms a reflector cup for each POSD. The electrical contacts on the bottom surface of each POSD are exposed, and thus, are accessible for electrical connections to other circuitry. Where the optoelectronic apparatus includes a plurality of POSDs, the light reflective molding compound also connects neighboring POSDs to one another.

Abstract: A method for manufacturing a plurality of optoelectronic apparatuses include attaching bottom surfaces of a plurality of packaged optoelectronic semiconductor devices (POSDs) to a carrier substrate (e.g., a tape) so that there is a space between each POSD and its one or more neighboring POSD(s). A light reflective molding compound is molded around a portion each of the POSDs attached to the carrier substrate so that a reflector cup is formed from the light reflective molding compound for each of the POSDs. The light reflective molding compound can also attach the POSDs to one another. Alternatively, an opaque molding compound can be molded around each POSD/reflector cup to attach the POSDs/reflector cups to one another and form a light barrier between each POSD and its neighboring POSD(s). The carrier substrate is thereafter removed so that electrical contacts on the bottom surfaces of the POSDs are exposed.

Abstract: Packaged light detector semiconductor devices (PLDSDs), methods for manufacturing PLDSDs, and systems including a PLDSD are described herein. In an embodiment, a PLDSD includes a light detector die having a surface including an active photosensor region, and a non-imaging optical concentrator including an entrance aperture and an exit aperture axially aligned with one another and with the active photosensor region. A molding material forms the non-imaging optical concentrator and encapsulates at least a portion of the surface of the light detector die that extends beyond the exit aperture of the non-imaging optical concentrator. The non-imaging optical concentrator concentrates light from the entrance aperture toward the exit aperture and onto the active photosensor region.

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.

Abstract: A method for manufacturing a plurality of optoelectronic apparatuses include attaching bottom surfaces of a plurality of packaged optoelectronic semiconductor devices (POSDs) to a carrier substrate (e.g., a tape) so that there is a space between each POSD and its one or more neighboring POSD(s). A light reflective molding compound is molded around a portion each of the POSDs attached to the carrier substrate so that a reflector cup is formed from the light reflective molding compound for each of the POSDs. The light reflective molding compound can also attach the POSDs to one another. Alternatively, an opaque molding compound can be molded around each POSD/reflector cup to attach the POSDs/reflector cups to one another and form a light barrier between each POSD and its neighboring POSD(s). The carrier substrate is thereafter removed so that electrical contacts on the bottom surfaces of the POSDs are exposed.

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.

Abstract: An optical sensor device, according to an embodiment of the present invention, includes a light source and a light detector. The light source includes one or more light emitting elements, and the light detector includes one or more light detecting elements. A first opaque light barrier portion, between the light source and the light detector, is configured to block light from being transmitted directly from the light source to the light detector. A second opaque light barrier portion, extending from the first opaque light barrier portion in a direction towards the light source, is configured to reduce an amount of specular reflections that would occur if a light transmissive cover plate were placed over the optical sensor device.

Abstract: An optical sensor device comprises a light source, a light detector, and an opaque light barrier including a first portion to block light from being transmitted directly from the source to the detector. A second portion of the light barrier extends from the first portion in a direction towards the light source, such that a portion of the second portion covers at least a portion of light emitting element(s) of the source, to reduce an amount of specular reflections, if a light transmissive cover plate were placed over the sensor. Additionally, a third portion of the barrier can extend from the first portion, in a direction towards to the detector, such that a portion of the third portion covers at least a portion of light detecting element(s) of the detector, to reduce an amount of specular reflections that would be detected by the detecting element(s) of the detector, if a light transmissive cover plate were placed over the sensor. Additionally, an off-centered lens can cover a portion of the light source.

Abstract: An optical sensor device comprises a light source, a light detector, and an opaque light barrier including a first portion to block light from being transmitted directly from the source to the detector. A second portion of the light barrier extends from the first portion in a direction towards the light source, such that a portion of the second portion covers at least a portion of light emitting element(s) of the source, to reduce an amount of specular reflections, if a light transmissive cover plate were placed over the sensor. Additionally, a third portion of the barrier can extend from the first portion, in a direction towards to the detector, such that a portion of the third portion covers at least a portion of light detecting element(s) of the detector, to reduce an amount of specular reflections that would be detected by the detecting element(s) of the detector, if a light transmissive cover plate were placed over the sensor. Additionally, an off-centered lens can cover a portion of the light source.

Abstract: An optical sensor device, according to an embodiment of the present invention, includes a light source and a light detector. The light source includes one or more light emitting elements, and the light detector includes one or more light detecting elements. A first opaque light barrier portion, between the light source and the light detector, is configured to block light from being transmitted directly from the light source to the light detector. A second opaque light barrier portion, extending from the first opaque light barrier portion in a direction towards the light source, is configured to reduce an amount of specular reflections that would occur if a light transmissive cover plate were placed over the optical sensor device.

Abstract: Provided herein are optical sensor devices, methods for making the same, and systems including the same. An optical sensor device, according to an embodiment, includes a light detector die and a light source die attached to the same or different die attachment substrates so that there is a space between the light source die and the light detector die. A light transmissive material covers the light detector die, the light source die and at least a portion of the space between the light detector die and the light source die. A groove is formed (e.g., saw, blade or laser cut, or cast) in the light transmissive material between the light detector die and the light source die, and an opaque material is put within the groove to provide a light barrier between the light detector die and the light source die.

Abstract: Processing techniques for various modular components provide various surface mount structures for single device components (10) and multiple device components (FIGS. 6 and 7) suitable as character displays. The technique beings with a slab of substrate material 12 patterned on both sides. Plated through holes (33, 43) connecting back side terminals (19, 20) to front side connective strips (22, 24) are formed. Devices (15, 16) are mounted to land areas (13, 34) and wire bonded to connecting pads (14). The front side is coated with epoxy to encapsulate the devices in a layer having an outer surface formed into optional lenses (262, 263). The slab is then separated to provide the modular components.

Abstract: Processing techniques for various surface mount modular components provide various structures for single device components (10) and multiple device components (FIGS. 6 and 7) suitable as character displays. The technique beings with a slab of substrate material 12 patterned on both sides. Plated through holes (33, 43) connecting back side terminals (19, 20) to front side connective strips (22, 24) are formed. Devices (15, 16) are mounted to land areas (13, 34) and wire bonded to connecting pads (14). The front side is coated with epoxy to encapsulate the devices in a layer having an outer surface formed into optional lenses (262, 263). The slab is then separated to provide the modular components.

Abstract: Processing techniques for various modular components provide various surface mount structures for single device components (10) and multiple device components (FIGS. 6 and 7) suitable as character displays. The technique beings with a slab of substrate material 12 patterned on both sides. Plated through holes (33, 43) connecting back side terminals (19, 20) to front side connective strips (22, 24) are formed. Devices (15, 16) are mounted to land areas (13, 34) and wire bonded to connecting pads (14). The front side is coated with epoxy to encapsulate the devices in a layer having an outer surface formed into optional lenses (262, 263). The slab is then separated to provide the modular components.

Abstract: Processing techniques for various surface mount modular components provide various structures for single device components (10) and multiple device components (FIGS. 6 and 7) suitable as character displays. The technique beings with a slab of substrate material 12 patterned on both sides. Plated through holes (33, 43) connecting back side terminals (19, 20) to front side connective strips (22, 24) are formed. Devices (15, 16) are mounted to land areas (13, 34) and wire bonded to connecting pads (14). The front side is coated with epoxy to encapsulate the devices in a layer having an outer surface formed into optional lenses (262, 263). The slab is then separated to provide the modular components.