A display component includes a transflective layer, a reflective layer, and at least one sidewall. The reflective layer is arranged opposing to the transflective layer, and the at least one sidewall is arranged between the reflective layer and the transflective layer. The transflective layer, the reflective layer, and the at least one sidewall are together configured, upon an input of an incident light through the transflective layer, to output a light of a target color out through the transflective layer. One or more of the at least one sidewall comprise at least one light-conversion layer configured to emit a light of the target color upon excitement by a light of a different color shedding thereupon. The display component can be configured to output a red light, a green light, or a blue light.

Disclosed is a method to modify the superconductive properties of a potentially or effectively superconductive material. The method includes providing a reflective or photonic structure and placing said superconductive material in or on the structure. The method also includes providing a structure which has an electromagnetic mode which is resonant with a transition in the material and controlling, in particular enhancing, the superconductivity, and thus the mobility of the charge carriers. This results in a higher operating temperature and an increased electrical current in the material, by means of strongly coupling the material to the local electromagnetic vacuum field and exploiting the formation of states of spatial extension corresponding to the mode volume of the electromagnetic resonance. Also disclosed is an electronic, electro-optical or optoelectronic device including superconductive material located in or on a reflective or photonic structure.

A tunable optical filter provides a narrow passband centered around the wavelength of the laser beam to limit ambient light noise impinging on a primary photodetector. As the wavelength changes due to temperature or other effects, the wavelength is indirectly measured and used to shift the passband of the filter to center it on the shifted wavelength. A portion of the emitted beam is diverted through the same tunable filter to a feedback photodetector. The output of the feedback photodetector will be at a maximum value when the tunable filter passband is centered on the laser beam wavelength. By controlling the passband of the tunable filter to maximize the feedback photodetector output, the passband remains centered on the laser wavelength. The tunable filter is a Liquid Crystal Tunable Filter (LCTF) or another tunable filter large enough to pass both reflected and feedback light to the primary and feedback photodetectors.

Disclosed are a reflective display substrate and a method for fabricating the same, a display panel, and a display device. The reflective display substrate includes a base substrate and a resonant cavity layer. The base substrate has a plurality of pixel regions. The resonant cavity layer is disposed on a first side of the base substrate. The resonant cavity layer includes a plurality of resonant cavities. The plurality of resonant cavities are in one-to-one correspondence with the plurality of pixel regions. The resonant cavity is disposed in the corresponding pixel region. The resonant cavity is configured to enhance reflection of light of a first color in incident light and reduce reflection of light of a second color in the incident light.

A multi-spectral imaging system utilizing tunable optics is disclosed. Various disclosed systems include a tunable optical filter coupled to a broadband imaging system. The tunable optical filter allows discrete infrared wavelengths to pass to the broadband imaging system so that monochromatic infrared images of a scene may be captured. An image processing system may process selected monochromatic infrared images by using a ratio technique to generate an emissivity-independent thermal image of the scene. The tunable optical filter may also be used to adjust a quality factor and control an amount of radiated energy that is passed to an image sensor of the broadband imaging system thereby acting as an aperture to account for both low and high radiance portions of the scene.

A source for providing electromagnetic radiation within a particular spectral range, including: a ring-shaped optical resonator for circulating a plurality of wavelength bands including: a first optical phase modulator, a first chomatic dispersion device, a second optical phase modulator, a multi-line spectral domain filter, a second chromatic dispersion device, and an optical amplifier; a controller coupled to the first optical phase modulator and the second optical phase modulator which is configured to drive the first optical phase modulator with a first waveform and the second optical phase modulator with a second waveform, the first chromatic dispersion device being configured between the first optical phase modulator and the second optical phase modulator to provide chromatic dispersion so as to subject each of the plurality of wavelength bands to a respective plurality of different time delays, the first and second optical phase modulators being configured to create spectral broadening.

This disclosure describes a capacitively controlled Fabry-Perot interferometer which comprises a first mirror layer with a first metallic thin-film layer embedded in a first insulating layer and a second mirror layer with a second metallic thin-film layer embedded within a second insulating layer. A control region in the first metallic thin-film layer is at least partly aligned in an actuation direction with a control region in the second metallic thin-film layer. The interferometer also comprises a first control electrode and a first dielectric layer, and the first dielectric layer lies between the first control electrode and at least a part of the control region of the first metallic thin-film layer.

A gain medium is pumped by a source. An optical wave passes through a photonic integrated circuit (PIC) that comprises: a substrate comprising silicon, multiple photonic structures, an input port coupling an optical wave into a waveguide formed in the PIC, and an output port coupling an optical wave out of a waveguide formed in the PIC. Propagation of an optical wave circulating around a closed path of a laser ring cavity is limited using an optical isolator such that, when the pump source exceeds a lasing threshold, the optical wave propagates in a single direction through the gain medium and PIC. From an output coupler, an output is provided that comprises a fraction (e.g., >0.5) of the power of an optical wave that is incident upon the output coupler, and remaining power of the optical wave is redirected around the closed path of the laser ring cavity.

A tunable optical filter device. The device comprises a first substrate (101) provided with a first reflective structure (106) and a thin film (103) provided with a second reflective structure (107), the outer peripheries of the surfaces of the first substrate (101) and the thin film (103) having the reflective structures are mutually bonded by means of bonding compounds (102) so as to form a cavity between the reflective structures, and a piezoelectric thin film structure (108) is provided on a surface of the thin film (103) at the cavity side. The tunable optical filter device can avoid a pull-in effect caused by capacitor driving, thereby improving the movable range of the thin film (103), and correspondingly expanding the tunable range of the spectrum of the Fabry-Perot cavity; in addition, the tunable optical filter device can be applied to a device with a limited size, such as a micro spectrometer, a miniaturized or even a mini-hyperspectral camera or a mobile phone.

Optical system comprising two optical fibres which are configured to define between them a Fabry-Perot cavity, and a connecting element bonded to each of the two optical fibres, the connecting element defining a through-passage, at least one of the two optical fibres comprising an end portion arranged in the through-passage and bonded to the connecting element, the two optical fibres extending along an axis and being separated from one another by a distance Le parallel to the axis, one of the optical fibres being bonded to the connecting element at a first bonding zone, and the other optical fibre being bonded to the connecting element at a second bonding zone separated from the first bonding zone by distance parallel to the axis.