Abstract: A semiconductor package that is a proximity sensor includes a light transmitting die, a light receiving die, an ambient light sensor, a cap, and a substrate. The light receiving die and the light transmitting die are coupled to the substrate. The cap is coupled to the substrate forming a first chamber around the light transmitting die and a second chamber around the light receiving die. The cap further includes a recess with contact pads. The ambient light sensor is mounted within the recess of the cap and coupled to the contact pads. The cap includes electrical traces that are coupled to the contact pads within the recess coupling the ambient light sensor to the substrate. By utilizing a cap with a recess containing contact pads, a proximity sensor can be formed in a single semiconductor package all while maintaining a compact size and reducing the manufacturing costs of proximity sensors.

Abstract: An image sensing device includes an interconnect layer and a number of grid array contacts arranged on a bottom side of the interconnect layer. An image sensor integrated circuit (IC) is carried by the interconnect layer and has an image sensing surface. A number of electrical connections are coupled between the image sensor IC and an upper side of the interconnect layer. A transparent plate overlies the image sensing surface of the image sensor IC. A cap is carried by the interconnect layer and has an opening overlying transparent plate and the image sensing surface. The cap has an upper wall spaced above the interconnect layer and the image sensor IC to define an internal cavity and the cap defines an air vent coupled to the internal cavity.

Abstract: An optical detection sensor functions as a proximity detection sensor that includes an optical system and a selectively transmissive structure. Electromagnetic radiation such as laser light can be emitted through a transmissive portion of the selectively transmissive structure. A reflected beam can be detected to determine the presence of an object. The sensor is formed by encapsulating the transmissive structure in a first encapsulant body and encapsulating the optical system in a second encapsulant body. The first and second encapsulant bodies are then joined together. In a wafer scale assembling the structure resulting from the joined encapsulant bodies is diced to form optical detection sensors.

Abstract: One or more embodiments are directed to system in package (SiP) for optical devices, such as proximity sensing or optical ranging devices. One embodiment is directed to an optical sensor package that includes a substrate, a sensor die coupled to the substrate, a light-emitting device coupled to the substrate, and a cap. The cap is positioned around side surfaces of the sensor die and covers at least a portion of the substrate. The cap includes first and second sidewalls, an inner wall having first and second side surfaces and a mounting surface, and a cover in contact with the first and second sidewalls and the inner wall. The first and second side surfaces are transverse to the mounting surface, and the inner wall includes an opening extending into the inner wall from the mounting surface. A first adhesive material is provided on the sensor die and at least partially within the opening, and secures the inner wall to the sensor die.

Abstract: One or more embodiments are directed to system in package (SiP) for optical devices, including proximity sensor packaging. One embodiment is directed to optical sensor that includes a substrate, an image sensor die and a light-emitting device. A first surface of the image sensor die is coupled to the substrate, and a recess is formed extending into the image sensor die from the first surface toward a second surface of the image sensor die. A light transmissive layer is formed in the image sensor die between the recess and the first surface. The optical sensor further includes a light-emitting device that is coupled to the substrate and positioned within the recess formed in the image sensor die.

Abstract: A semiconductor-based multi-sensor module integrates miniature temperature, pressure, and humidity sensors onto a single substrate. Pressure and humidity sensors can be implemented as capacitive thin film sensors, while the temperature sensor is implemented as a precision miniature Wheatstone bridge. Such multi-sensor modules can be used as building blocks in application-specific integrated circuits (ASICs). Furthermore, the multi-sensor module can be built on top of existing circuitry that can be used to process signals from the sensors. An integrated multi-sensor module that uses differential sensors can measure a variety of localized ambient environmental conditions substantially simultaneously, and with a high level of precision. The multi-sensor module also features an integrated heater that can be used to calibrate or to adjust the sensors, either automatically or as needed.

Abstract: A universal electrochemical micro-sensor can be used either as a biosensor or an environmental sensor. Because of its small size and flexibility, the micro-sensor is suitable for continuous use to monitor fluids within a live subject, or as an environmental monitor. The micro-sensor can be formed on a reusable glass carrier substrate. A flexible polymer backing, together with a set of electrodes, forms a reservoir that contains an electrolytic fluid chemical reagent. During fabrication, the glass carrier substrate protects the fluid chemical reagent from degradation. A conductive micromesh further contains the reagent while allowing partial exposure to the ambient biological or atmospheric environment. The micromesh density can be altered to accommodate fluid reagents having different viscosities. Flexibility is achieved by attaching a thick polymer tape and peeling away the micro-sensor from the glass carrier substrate.

Abstract: A single chip integrated circuit (IC) package includes a die pad, and a spacer ring on the die pad defining a solder receiving area. A solder body is on the die pad within the solder receiving area. An IC die is on the spacer ring and is secured to the die pad by the solder body within the solder receiving area. Encapsulating material surrounds the die pad, spacer ring, and IC die. For a multi-chip IC package, a dam structure is on the die pad and defines multiple solder receiving areas. A respective solder body is on the die pad within a respective solder receiving area. An IC die is within each respective solder receiving area and is held in place by a corresponding solder body. Encapsulating material surrounds the die pad, dam structure, and plurality of IC die.

Abstract: The embodiments of the present disclosure relate to a semiconductor device and a manufacturing method therefor. The semiconductor device comprises: a die attachment pad; a stud bump located on the die attachment pad and in direct contact with the die attachment pad; a first die located on the stud bump and electrically coupled to the stud bump; and a conductive attachment material located between the die attachment pad and the first die.

Abstract: A microelectronic device capable of detecting multiple gas constituents in ambient air can be used to monitor air quality. The microelectronic air quality monitor includes a plurality of temperature-sensitive gas sensors tuned to detect different gas species. Each gas sensor is tuned by programming an adjacent heater. An insulating air pocket formed below the sensor helps to maintain the sensor at a desired temperature. A temperature sensor may also be integrated with each gas sensor to provide additional feedback control. The heater, temperature sensor, and gas sensors are in the form of patternable thin films integrated on a single microchip. The device can be incorporated into computer workstations, smart phones, clothing, or other wearable accessories to function as a personal air quality monitor that is smaller, more accurate, and less expensive than existing air quality sensors.

Abstract: A proximity sensor is provided according to the embodiments of the present disclosure, comprising: a sensor chip; a light-emitting device; a substrate, the sensor chip and the light-emitting device being located on the substrate; a transparent molding material covering a light-emitting surface of the light-emitting device; and a non-transparent molding material separating the transparent molding material from the sensor chip.

Abstract: A package packaged with a cap. The package features trenches, through holes, and a non-conductive coupling element forming a locking mechanism integrated embedded or integrated within a substrate. The package has a cap coupled to the non-conductive coupling element through ultrasonic plastic welding. The package protects the dice from an outside environment or external stresses or both. A method is desired to form package to reduce glue overflow defects in the package. Fabrication of the package comprises drilling holes in a substrate; forming trenches in the substrate; forming a non-conductive coupling element in the through holes and the trenches to form a locking mechanism; allowing the non-conductive coupling element to harden and cure; coupling a die or dice to the substrate; and coupling a cap to the non-conductive coupling element to protect the die or dice from an outside environment or external stresses or both.

Abstract: An electronic device includes a substrate, an optical sensor coupled to the substrate, and an optical emitter coupled to the substrate. A lens is aligned with the optical emitter and includes an upper surface and an encapsulation bleed stop groove around the upper surface. An encapsulation material is coupled to the substrate and includes first and second encapsulation openings therethrough aligned with the optical sensor and the lens, respectively.

Abstract: One or more embodiments are directed to semiconductor packages that include a pillar and bump structures. The semiconductor packages include a die that has recess at a perimeter of the semiconductor die. The semiconductor package includes an encapsulation layer that is located over the semiconductor die filling the recess and surrounding side surfaces of the pillars. The package may be formed on a wafer with a plurality of die and may be singulated into a plurality of packages.

Abstract: The embodiments of the present disclosure provide a proximity sensor, an electronic apparatus and a method for manufacturing a proximity sensor. The proximity sensor comprises a sensor chip, a light-emitting device, a transparent molding material and a non-transparent molding material, wherein the sensor chip comprises a sensor region; the light-emitting device is located on the sensor chip and is electrically coupled to the sensor chip; the transparent molding material at least covers a light-emitting surface of the light-emitting device; and the non-transparent molding material isolates the transparent molding material from the sensor region.

Abstract: Embodiments of the present disclosure are directed to optical packages having a package body that includes a light protection coating on at least one surface of a transparent material. The light protection coating includes one or more openings to allow light to be transmitted to the optical device within the package body. In one embodiment, the light protection coating and the openings allow substantially perpendicular radiation to be directed to the optical device within the package body. In one exemplary embodiment the light protection coating is located on an outer surface of the transparent material. In another embodiment, the light protection coating is located on an inner surface of the transparent material inside of the package body.

Abstract: A semiconductor-based multi-sensor module integrates miniature temperature, pressure, and humidity sensors onto a single substrate. Pressure and humidity sensors can be implemented as capacitive thin film sensors, while the temperature sensor is implemented as a precision miniature Wheatstone bridge. Such multi-sensor modules can be used as building blocks in application-specific integrated circuits (ASICs). Furthermore, the multi-sensor module can be built on top of existing circuitry that can be used to process signals from the sensors. An integrated multi-sensor module that uses differential sensors can measure a variety of localized ambient environmental conditions substantially simultaneously, and with a high level of precision. The multi-sensor module also features an integrated heater that can be used to calibrate or to adjust the sensors, either automatically or as needed.

Abstract: An optical detection sensor functions as a proximity detection sensor that includes an optical system and a selectively transmissive structure. Electromagnetic radiation such as laser light can be emitted through a transmissive portion of the selectively transmissive structure. A reflected beam can be detected to determine the presence of an object. The sensor is formed by encapsulating the transmissive structure in a first encapsulant body and encapsulating the optical system in a second encapsulant body. The first and second encapsulant bodies are then joined together. In a wafer scale assembling the structure resulting from the joined encapsulant bodies is diced to form optical detection sensors.

Abstract: One or more embodiments are directed to system in package (SiP) for optical devices, such as proximity sensing or optical ranging devices. One embodiment is directed to an optical sensor package that includes a substrate, a sensor die coupled to the substrate, a light-emitting device coupled to the substrate, and a cap. The cap is positioned around side surfaces of the sensor die and covers at least a portion of the substrate. The cap includes first and second sidewalls, an inner wall having first and second side surfaces and a mounting surface, and a cover in contact with the first and second sidewalls and the inner wall. The first and second side surfaces are transverse to the mounting surface, and the inner wall includes an opening extending into the inner wall from the mounting surface. A first adhesive material is provided on the sensor die and at least partially within the opening, and secures the inner wall to the sensor die.

Abstract: One or more embodiments disclosed herein are directed to a chip scale package camera module that includes a glass interposer between a lens and an image sensor. In some embodiments, the glass interposer is made from one or more layers of optical quality glass and includes an infrared filter coating. The glass interposer also includes electrically conductive paths to connect the image sensor, mounted on one side of the glass interposer, with other components such as capacitors, which may be mounted on a different side of the glass interposer, and the rest of the camera system. The conductive layers include traces and vias that are formed in the glass interposer in areas away from the path of light in the camera module, such that the traces and vias do not block the light between the lens and the image sensor.