A color changing or beam steering photonic device, which combines a high contrast metastructure (HCM) having a plurality of high index grating structures, into a low index membrane. In response to physical (or electrical) deformation of the membrane the low index gaps between adjacent grating bars changes which results in changing reflectance and transmission angles for steering a single wavelength of light and for causing a color change in said photonic device when subject to multiple light wavelengths. Deformation can result from direct physical stimulus, conversion from electrical or thermal to physical, and so forth. Refractive index change can also be initiated by carrier injection through electrodes. The apparatus is exemplified for use in color displays, beam steering, labeling micro entities, mechanical deformation sensing, camouflage, anti-counterfeiting, and other fields.

A filter to transmit incident radiation at a predetermined incidence angle includes a plurality of photonic crystal structures disposed substantially along a surface normal direction of the filter. The photonic crystal structure includes a multilayer cell that comprises a first layer having a first dielectric permittivity, and a second layer having a second dielectric permittivity different from the first dielectric permittivity. The first layer and the second layer define a Brewster angle substantially equal to the predetermined incidence angle based on the first dielectric permittivity and the second permittivity. Each photonic crystal structure in the plurality of photonic crystal structures defines a respective bandgap, and the respective bandgaps of the plurality of photonic crystal structures, taken together, cover a continuous spectral region of about 50 nm to about 100 mm.

The present application discloses a display panel free of a liquid crystal layer including a base substrate, and an array of a plurality of pixels on the base substrate, each of the plurality of pixels comprising at least one subpixel. Each subpixel includes an electroactive layer on the base substrate; and a light transmission layer on the base substrate configured to be actuated by the electroactive layer so that light transmittance of the light transmission layer in the at least one subpixel changes in response to a change in an electrical signal applied to the electroactive layer to achieve levels of gray scale; wherein the light transmission layer is reversibly deformable.

The present invention relates to a Photoelastic Modulator (PEM), particularly to a novel polarized light modulator structure based on a photoelastic effect. The PEM, which controls driving voltages of two groups of piezoelectric actuators, is able to implement polarized light modulation having a relatively large optical path difference, and polarized light modulator having a fast modulation shaft moving circumferentially, and the PEM operates stably without a moving component. The present invention includes the piezoelectric actuators, a light pass crystal and a driver controller. Two light pass faces of the light pass crystal are parallel regular octagons directly facing each other, and identical rectangles are formed by side faces of the light pass crystal. The piezoelectric actuators are in soft connection with middle positions of the rectangles by connection rubber layers. The width directions of the piezoelectric actuators are consistent with the direction of the light pass thickness of the light pass crystal, and the widths are slightly larger than the light pass thickness. The piezoelectric actuators are connected with electric output ends on the driver controller by electric adapters. This aspect is mainly applied to PEMs.

There is described an optical apparatus having an optical fiber link propagating an optical signal; a first device coupled with a first fiber portion of the link and configured for imparting a phase changing contribution thereto; and a second device coupled with a second fiber portion of the link and configured for imparting a phase changing contribution thereto, the second device operating within a second response frequency range having a maximum value greater than a maximum value of a first response frequency range of the first device; wherein, upon the optical signal experiencing a phase change including a frequency value greater than the first response frequency range, the first device imparts a first phase change at a first response frequency value within the first response frequency range, and the second device imparts a second phase change at a second response frequency value greater than the first response frequency range.

An apparatus includes an elastically deformable optical element holder situated to receive an optical element having a plurality of holder contact surfaces, the optical element holder including a plurality of receiving portions adjacent to an aperture and corresponding to respective holder contact surfaces, each receiving portion displaceable through deformation of the optical element holder so that the optical element is insertable in the aperture so as to be cushionably supported in a predetermined position with the receiving portions in contact with the respective holder contact surfaces.

The present application discloses a 3D imaging method and apparatus, which divide a source 3D image light into two polarized light beams carrying image information through a birefringence effect, adjust optical paths of the two polarized light beams obtained through birefringence, and control the two polarized light beams to be alternately irradiated, thereby achieving 3D imaging; since the implementation of the above imaging method only requires one imaging apparatus having corresponding functions, the present application can simplify the system structure and reduce the system cost relative to a conventional 3D projection technology that requires two imaging devices; moreover, a viewer can directly see, with no need to wear corresponding 3D glasses, a 3D image due to the parallax caused by alternate irradiation of two polarized light beams carrying image information out of a projection device. As a result, the investment in configuring 3D glasses can be saved and the system cost is further reduced.

Provided is a display device. The display device includes a display panel, a contact sensitive device on the display panel, and a linear polarizer on the contact sensitive device. The contact sensitive device includes an electro-active layer which is uniaxially elongated and configured to retard a phase of incident light. Since the display device includes the contact sensitive device having the electro-active layer configured to retard the phase of the incident light, a separate phase retardation film for suppressing external light reflection may be omitted. As a result, the thickness of the display device may be decreased and manufacturing cost of the display device may be reduced.

An imaging system includes an indicator installed around an antenna, wherein optical characteristics of the indicator change as a function of an electromagnetic field formed by the antenna, an imaging apparatus for imaging a change in optical characteristics of the indicator, a transmitter for radiating radio waves toward the antenna, and a receiver for receiving a signal from the antenna.

The present invention provides an array substrate comprising a transparent substrate and a polarizer attached on the transparent substrate, the polarizer comprises a first protective layer in contact with the transparent substrate, and a relational expression is satisfied between the first protective layer and the transparent substrate, 0|C|1.010.sup.13, wherein C is defined by the equation

[00001]$C=\frac{C_{100}.Math.{}_{100}.Math.d_{100}}{{}_{100}.Math.d_{100}+{}_{200}.Math.d_{200}}+\frac{C_{200}.Math.{}_{200}.Math.d_{200}}{{}_{100}.Math.d_{100}+{}_{200}.Math.d_{200}}.$

When designing an array substrate provided by this invention, it is not required to consider the improvement of the material of the polarizer, and it may be ensured that the change of photoelastic birefringence of a finally formed array substrate is zero (or close to zero) in the case of being subjected to stress by only adjusting the thickness of a first protective layer or the material of the first protective layer, such that the phenomenon of light leakage of a finally formed liquid crystal display panel generated due to photoelastic birefringence may be eliminated or reduced. This invention further provides a display panel, a display apparatus, and a method for producing an array substrate.