A composite substrate (100) for a photonic crystal element includes: an electro-optical crystal substrate (10) having an electro-optical effect; an optical loss-suppressing and cavity-processing layer (20) arranged on one surface of the electro-optical crystal substrate (10); and a support substrate (30) integrated with the electro-optical crystal substrate (10) through the optical loss-suppressing and cavity-processing layer (20).

A light detection and ranging (LiDAR) device comprising: a laser emitting chip configured to emit laser, a laser detecting chip configured to detect laser, an emitting optic module configured to guide laser generated from the laser emitting chip to the outside of the LiDAR device, a detecting optic module configured to guide laser received from the outside of the LiDAR device to the laser detecting chip, an emitting optic holder located between the laser emitting chip and the emitting optic module, and an at least one emitting optic fixer located between the emitting optic holder and the emitting optic module, wherein the at least one emitting optic fixer is configured to fix a relative position between the laser emitting chip and the emitting optic module.

A luminaire includes a first waveguide having a first primary light emitting surface directed in a first direction and a first secondary light emitting surface directed in a second direction. A second waveguide having a second primary light emitting surface directed in the second direction and a second secondary light emitting surface directed in the first direction. A first plurality of LEDs are optically coupled to the first waveguide and a second plurality of LEDs are optically coupled to the second waveguide. The first and second waveguides are independently operable. The first and second plurality of LEDs may comprise LED groups where each of the LED groups are independently controllable. The light emission pattern and light properties of the emitted light are controllable

Luminaires are described herein employing waveguides and associated architectures for dynamic alteration of illuminance distribution patterns. The waveguide includes a light extraction component. The waveguide transmits light from a light source to the light extraction component by total internal reflection (TIR). The light extraction component includes one or more reversibly moveable surfaces for altering illuminance distribution patterns of the luminaire in response to one or more forces applied to the light extraction component by a force application assembly of the luminaire.

Luminaires are described herein employing waveguides and associated architectures for dynamic alteration of illuminance distribution patterns. The waveguide includes a light extraction component. The waveguide transmits light from a light source to the light extraction component by total internal reflection (TIR). The light extraction component includes one or more reversibly moveable surfaces for altering illuminance distribution patterns of the luminaire in response to one or more forces applied to the light extraction component by a force application assembly of the luminaire.

A light detection and ranging (LiDAR) device comprising: a laser emitting chip configured to emit laser, a laser detecting chip configured to detect laser, an emitting optic module configured to guide laser generated from the laser emitting chip to the outside of the LiDAR device, a detecting optic module configured to guide laser received from the outside of the LiDAR device to the laser detecting chip, an emitting optic holder located between the laser emitting chip and the emitting optic module, and an at least one emitting optic fixer located between the emitting optic holder and the emitting optic module, wherein the at least one emitting optic fixer is configured to fix a relative position between the laser emitting chip and the emitting optic module.

Luminaires are described herein employing waveguides and associated architectures for dynamic alteration of illuminance distribution patterns. The waveguide includes a light extraction component. The waveguide transmits light from a light source to the light extraction component by total internal reflection (TIR). The light extraction component includes one or more reversibly moveable surfaces for altering illuminance distribution patterns of the luminaire in response to one or more forces applied to the light extraction component by a force application assembly of the luminaire.

In one aspect, a hyperspectral image measurement device is provided to include: a main body; an illumination module disposed in the main body and including LEDs having different peak wavelengths to irradiate light to a subject; a camera disposed on the main body and receiving light reflected from the subject to acquire an image of the subject; a barrel having a contact surface contacting the subject, the contact surface located to be spaced apart from the illumination module and the camera module by a predetermined distance; and a reference cover located on the contact surface and including a standard reflection layer for reflecting light irradiated from the illumination module toward the camera module.

In one aspect, a hyperspectral image measurement device is provided to include: a main body; an illumination module disposed in the main body and including LEDs having different peak wavelengths to irradiate light to a subject; a camera disposed on the main body and receiving light reflected from the subject to acquire an image of the subject; a barrel having a contact surface contacting the subject, the contact surface located to be spaced apart from the illumination module and the camera module by a predetermined distance; and a reference cover located on the contact surface and including a standard reflection layer for reflecting light irradiated from the illumination module toward the camera module.

An optical modulator includes a substrate having a first face and a second face; an input port provided on the first face; a first waveguide provided on the substrate, the waveguide being connected to the input port; a first coupler provided on the substrate, the first coupler being optically connected to the first waveguide; an output port provided on the first face of the substrate, the output port being optically connected to the first coupler; and a first anti-reflection coating provided on the second face. The first face and the second face are arranged along a first direction. The first face and the second face extend in a direction intersecting the first direction. The first coupler extends in the first direction.