The present disclosure relates to a microelectronics package with optical sensors and/or thermal sensors. The disclosed microelectronics package includes a module substrate, a thinned flip-chip die with an upper surface that includes a first surface portion and a second surface portion surrounding the first surface portion, and a first mold compound component. The thinned flip-chip die is attached to the module substrate and includes a device layer with sensor structure integrated at a top portion of the device layer. Herein, the sensor structure is below the first surface portion and not below the second surface portion. The first mold compound component is formed over the second surface portion to define a first cavity over the upper surface of the thinned flip-chip die. The first mold compound component is not over the first surface portion, and the first surface portion is exposed at the bottom of the first cavity.

Various optoelectronic modules are described and include one or more optoelectronic devices. Each optoelectronic module includes one or more optoelectronic devices. Sidewalls laterally surround each optoelectronic device and can be in direct contact with sides of the optoelectronic device or, in some cases, with an overmold surrounding the optoelectronic device. The sidewalls can be composed, for example, of a vacuum injected material that is non-transparent to light emitted by or detectable by the optoelectronic device. The module also includes a passive optical element. Depending on the implementation, the passive optical element can be on a cover for the module, directly on a top surface of the optoelectronic device, or on an overmold surrounding the optoelectronic device. Methods of fabricating such modules are described as well, and can facilitate manufacturing the modules using wafer-level processes.

A purpose of the present invention is to provide an optical unit that is capable of effectively sealing one or a plurality of optical devices even without a special material, a special structure, etc. In an optical unit of the present invention, the sealing section (50) includes: a circular seal section (51) surrounding one or a plurality of optical devices (40) on a wiring substrate from an in-plane direction of the wiring substrate; and an inside filling section (52) with which inside of the seal section (51) is filled and that seals the one or plurality of optical devices (40). The optical devices (40) are each a light emitting unit, a light receiving device, an image sensor, an X-ray sensor, or a power generating device. The seal section (51) and the inside filling section (52) are each configured of a cured thermosetting resin. The inside filling section (52) has light transmittance that is higher than light transmittance of the seal section (51). The inside filling section (52) has a modulus of elasticity that is smaller than a modulus of elasticity of the seal section (51).

A color converter comprising at least one layer comprising at least one organic fluorescent colorant and at least one barrier layer having a low permeability to oxygen.

Provided is a sealing material that easily converts laser light to thermal energy, exhibits satisfactory fluidity, and is conducive to a reduction in its melting point. The sealing material includes 54.9 vol % to 99.9 vol % of glass powder, 0 vol % to 45 vol % of refractory filler powder, and 0.1 vol % to 10 vol % of a laser absorbing material, in which the glass powder includes as a glass composition, in terms of the following oxides in mass %, 70% to 90% of Bi.sub.2O.sub.3, 2% to 12% of B.sub.2O.sub.3, 1% to 15% of ZnO, 0.2% to 15% of CuO+Fe.sub.2O.sub.3, and 0.1% to 20% of MgO+CaO+SrO+BaO.

A sample-holding device for holding and lifting a sample includes a sample-holding surface facing the sample; and a positioning member provided at a peripheral part of the sample-holding surface, the positioning member comprising a contact part having an outward-facing part on a back side thereof; a first rounded or chamfered end; and a second rounded or chamfered end, wherein the contact part contacts with part of the sample when the sample is held or when the sample is off-point, wherein the first end is an end of a section comprising the contact part or a part smoothly continuing from the contact part, the end being on a distant side from the sample-holding surface, and the second end is an end of the outward-facing part, the end being located on a tipping side of the outward-facing part.

An electronic component includes a base, a laminate of a plurality of conductive metal material layers, and a solder layer made of AuSn alloy solder. The laminate is disposed on the base. The solder layer is disposed on the laminate. The laminate includes a surface layer made of Au as the conductive metal material layer constituting an outermost layer. The surface layer includes a solder layer-disposing region in which the solder layer is disposed and a solder layer-empty region in which the solder layer is not disposed. The solder layer-disposing region and the solder layer-empty region are spatially separated from each other.

A package for an optical semiconductor device includes an eyelet, a signal lead inserted in a through hole formed in the eyelet, and sealing glass sealing the signal lead in the through hole. The signal lead includes a first portion, a second portion and a third portion that are greater in diameter than the first portion and on opposite sides of the first portion, a first tapered portion extending from the second portion to the first portion, and a second tapered portion extending from the third portion to the first portion. The first portion and the first and second tapered portions are buried in the sealing glass. The total length of a part of the second portion in the sealing glass and a part of the third portion in the sealing glass is 0.2 mm or less.

This invention relates to an optical module package structure. A substrate is defined with a light receiving region and a light emitting region. A light receiving chip and a light emitting chip are disposed on the light receiving region and the light emitting region of the substrate, respectively. An electronic unit is disposed on the substrate and electrically connected to the light emitting chip. Two encapsulating gels are coated on each of the chips and the electronic unit. A cover is disposed on the substrate and has a light emitting hole and a light receiving hole, located above the light emitting chip and the light receiving chip, respectively. In this way, the package structure of the optical module of the present invention integrates passive components, functional ICs or dies into a module, and the optical module provides the functions of current limiting or function adjustment.

A detection device and a method of manufacturing the same are disclosed. The detection device includes a detection module and a housing module disposed on the detection module. The detection module includes a substrate, an emission unit, and a detection unit. The substrate includes an emission end area on which the emission unit is disposed, and a receiver end area on which the detection unit is disposed. The housing module includes a plastic housing unit having a receiving space and an opening, and a metallic shielding unit disposed on the plastic housing unit. The receiving space is divided into a first receiving space and a second receiving space by the metallic shielding unit, and the opening is divided into an emission hole and a detection hole by the metallic shielding unit. By the above-mentioned means, the distance between the emission hole and the detection hole is reduced.