An apparatus includes an optoelectronic module including a light emitting die and a light receiver die mounted on a PCB substrate. The optoelectronic module further includes an optical element on the light emitting die and an optical element on the light receiver die, the optical elements being composed of a first epoxy. A second epoxy laterally surrounds and is in contact with respective side surfaces of the light emitting die, the light receiver die and the optical elements, wherein the second epoxy provides an optical barrier between the light emitting die and the light receiver die. A method of manufacturing such modules is described as well.

An apparatus includes an optoelectronic module including a light emitting die and a light receiver die mounted on a PCB substrate. The optoelectronic module further includes an optical element on the light emitting die and an optical element on the light receiver die, the optical elements being composed of a first epoxy. A second epoxy laterally surrounds and is in contact with respective side surfaces of the light emitting die, the light receiver die and the optical elements, wherein the second epoxy provides an optical barrier between the light emitting die and the light receiver die. A method of manufacturing such modules is described as well.

The present disclosure relates to an optical sensor module, an optical sensing accessory, and an optical sensing device. An optical sensor module comprises a light source, a photodetector, and a substrate. The light source is configured to convert electric power into radiant energy and emit light to an object surface. The photodetector is configured to receive the light from an object surface and convert radiant energy into electrical current or voltage. An optical sensing accessory and an optical sensing device comprise the optical sensor module and other electronic modules to have further applications.

Disclosed are optical devices and methods of manufacturing optical devices. An optical device can include a substrate; an optical emitter chip affixed to the front surface of the substrate; and an optical sensor chip affixed to the front surface of the substrate. The optical sensor chip can include a main sensor and a reference sensor. The optical device can include an opaque dam separating the main optical sensor and the reference sensor. The optical device can include a first transparent encapsulation block encapsulating the optical emitter chip and the reference optical sensor and a second transparent encapsulation block encapsulating the main optical sensor. The optical device can include an opaque encapsulation material encapsulating the first transparent encapsulation block and the second transparent encapsulation block with a first opening above the main optical sensor and a second opening above the optical emitter chip.

Described herein are microfluidic devices and methods of detecting an analyte in a sample that includes flowing the sample though a microfluidic device, wherein the presence of the analyte is detected directly from the microfluidic device without the use of an external detector at an outlet of the microfluidic device. In a more specific aspect, detection is performed by incorporating functional nanopillars, such as detector nanopillars and/or light source nanopillars, into a microchannel of a microfluidic device.

An optical device includes a substrate, a light emitter, a light detector, a conductive structure, and an opaque material. The light emitter, the light detector and the conductive structure are disposed on a surface of the substrate and are electrically connected to traces on the surface of the substrate. The light emitter includes an emitting area facing the substrate. The light detector includes a receiving area facing the substrate. The light emitter emits light within a range of wavelengths, and the substrate passes the light emitted by the light emitter. The opaque material is disposed on the substrate, and absorbs or attenuates the light within the range of wavelengths.

The invention provides a photocoupler package. The photocoupler package includes a light-emitting diode (LED) mounted on a first lead frame, electrically connected to the first lead frame. A photodetector is mounted on a second lead frame, electrically connected to the second lead frame. A first insulating material is disposed on the first lead frame, surrounding the LED. A second insulating material is disposed on the second lead frame, surrounding the photodetector. A third insulating material encapsulates the first insulating material and the LED. A third insulating material also encapsulates the second insulating material and the photodetector. This photocoupler possesses high photocoupling efficiency, small volume, and superior high-isolation capability.

A light receiving and emitting element module includes a substrate; a light emitting element and a light receiving element on an upper surface of the substrate; a frame-shaped outer wall that on the upper surface of the substrate; and a light shielding wall that is positioned inside the outer wall and partitions an internal space of the outer wall into spaces respectively corresponding to the light emitting element and the light receiving element. The light shielding wall includes a light emitting element-side shading surface on the light emitting element side, a light receiving element-side shading surface on the light receiving element side, and a lower surface that is connected to each of the light emitting element-side shading surface and the light receiving element-side shading surface, and that faces the substrate. The lower surface has an inclined surface inclined with respect to the upper surface of the substrate.

In an optical touch panel including a first group of light emitting and receiving packages and a second group of light emitting and receiving packages provided on a display surface at opposite sides to each other, each of the light emitting and receiving packages is formed by one light emitting element and one light receiving element vertically arranged above the display surface. The light emitting element of each light emitting and receiving package of the first group opposes the light receiving element of one light emitting and receiving package of the second group, and the light emitting element of each light emitting and receiving package of the second group opposes the light receiving element of one light emitting and receiving package of the first group.

Embodiments are directed to a coupler system having an interposer configured to couple optical signals. The interposer includes at least one optoelectronic component formed on a glass substrate. The interposer further includes at least one waveguide formed on the glass substrate and configured to couple the optical signals to or from the at least one optoelectronic component, wherein the at least one waveguide comprises a waveguide material having grain diameters greater than about one micron and an optical loss less than about one decibel per centimeter of optical propagation.