According to an embodiment, a method of manufacturing an optical sensor package includes forming a partition wall in each of substrate units on a substrate strip, mounting sensor elements on each of the substrate units, the sensor elements including a light-emitting unit and a light-receiving unit, and forming a molding member, using an encapsulant, in each of the substrate units, wherein the partition wall is arranged between the light-emitting unit and the light-receiving unit.

A hybrid photonic-electric interposer that includes an electrical part having electrical signal paths and a photonic part having photonic signal paths, with the electrical signal paths and the photonic signal paths being formed in parallel planes. The photonic part includes a plurality of sets of light emitting devices, waveguides, and photodetectors. In each one of said sets, the respective light emitting device, waveguide, and photodetector are coplanar with one another. In some instances, the photonic part may be disposed underneath the electrical part with the waveguides of the photonic part arrayed under metal interconnect layers of the electrical part and surrounded by a low refractive index dielectric. The light emitting devices of the photonic part may be light emitting diodes or lasers, and each of the light emitting devices may be configured to be modulated directly by an electrical signal to transmit photonic signals according to a non-return-to-zero modulation scheme.

An optical module includes: a base having a first surface facing a first direction, and a second surface that faces the first direction and that is away from the first surface in a second direction orthogonal to the first direction; an optical element provided on the first surface; an optical fiber fixing portion including a groove configured to at least partially accommodate a core wire obtained by removing a coating from an optical fiber; and an alignment mark provided either at a first position away from the groove in a direction opposite to the second direction or at a second position shifted from the first position in a direction opposite to a third direction orthogonal to both of the first direction and the second direction, as viewed in the direction opposite to the first direction.

A display device includes a thin-film transistor layer disposed on a substrate and including thin-film transistors; and an emission material layer disposed on the thin-film transistor layer. The emission material layer includes light-emitting elements each including a first light-emitting electrode, an emissive layer and a second light-emitting electrode, light-receiving elements each including a first light-receiving electrode, a light-receiving semiconductor layer and a second light-receiving electrode, and a first bank disposed on the first light-emitting electrode and defining an emission area of each of the light-emitting elements. The light-receiving elements are disposed on the first bank.

A display device includes a thin-film transistor layer disposed on a substrate and including thin-film transistors; and an emission material layer disposed on the thin-film transistor layer. The emission material layer includes light-emitting elements each including a first light-emitting electrode, an emissive layer and a second light-emitting electrode, light-receiving elements each including a first light-receiving electrode, a light-receiving semiconductor layer and a second light-receiving electrode, and a first bank disposed on the first light-emitting electrode and defining an emission area of each of the light-emitting elements. The light-receiving elements are disposed on the first bank.

A display device provided with an image capturing function is provided. A display device with both high viewing angle characteristics and high image capturing performance is provided. The display device includes a light-emitting and light-receiving element and a color filter. The light-emitting and light-receiving element includes a light-emitting and light-receiving region having a function of emitting light of the first color and a function of receiving light of the second color. The color filter is positioned over the light-emitting and light-receiving element and has a function of transmitting the light of the first color and a function of blocking the light of the second color. The color filter includes an opening portion. The light-emitting and light-receiving region includes a portion positioned in the inside of the opening portion in the plan view.

An interconnect substrate includes a core layer that is translucent, a first photoelectric conversion member disposed on a first surface of the core layer, a first interconnect layer electrically connected to the first photoelectric conversion member, a second photoelectric conversion member disposed on a second surface of the core layer that is opposite the first surface, and a second interconnect layer electrically connected to the second photoelectric conversion member, wherein the first photoelectric conversion member and the second photoelectric conversion member are arranged at such positions as to exchange optical signals with each other through the core layer.

The present disclosure relates to packaging techniques in connection with packaging electrical and optical components within circuit packages. For example, one or more examples described herein involve techniques for packaging an electro-photonic circuit while preserving access to a grating coupler, which may involve using a sacrificial die in conjunction with a unique overmolding process.

The present disclosure relates to packaging techniques in connection with packaging electrical and optical components within circuit packages. For example, one or more examples described herein involve techniques for packaging an electro-photonic circuit while preserving access to a grating coupler, which may involve using a sacrificial die in conjunction with a unique overmolding process.

An optocoupler includes a light output chip and a light-sensing chip. A light-receiving surface of the light-sensing chip is disposed to face a light output surface of the light output chip. The light-sensing chip and the light output chip are a green light-emitting diode and a blue light-emitting diode, respectively. Accordingly, the optocoupler has a stable output performance at a working temperature ranging from 55 C. to 150 C. and a high response frequency.