An electrowetting device has an active matrix substrate including a plurality of first electrodes arrayed in a matrix shape, a plurality of TFTs, a plurality of first wiring lines extending along a row direction, and a plurality of second wiring lines extending along a column direction. The plurality of TFTs are disposed so as to have at least one of first and second relative arrangements. The first relative arrangement is a relative arrangement where two or more TFTs that are connected to any one of the plurality of first wiring lines alternately include, along the row direction: TFTs that are connected to the first electrodes belonging to one of a pair of rows adjoining the one first wiring line; and TFTs that are connected to the first electrodes belonging to the other row. The second relative arrangement is a relative arrangement where two or more TFTs that are connected to any one of the plurality of second wiring lines alternately include, along the column direction: TFTs that are connected to the first electrodes belonging to one of a pair of columns adjoining the one second wiring line; and TFTs that are connected to the first electrodes belonging to the other column.

A display panel includes a light waveguide layer and a first substrate disposed opposite to each other, and further including an electrowetting control layer disposed between the light waveguide layer and the first substrate, the electrowetting control layer including a first electrode layer, a second electrode layer, and a grating layer and an electrowetting layer which are disposed between the first electrode and the second electrode layer, the grating layer and the electrowetting layer are configured to operatively couple light with a set transmittance, a setting direction, and a set wavelength out of the light waveguide layer.

Disclosed is a liquid lens control circuit, which includes a liquid lens including a plurality of individual electrodes disposed in compartmental areas at the same level and a common electrode disposed at a different level from that of the individual electrodes, a voltage control circuit configured to supply voltages to the common electrode and at least one of the individual electrodes in the liquid lens in order to control an interface in the liquid lens, and a capacitance measuring circuit configured to calculate a capacitance between the common electrode and at least one of the individual electrodes in the liquid lens using a switched capacitor.

An apparatus includes a backlight, a color filter disposed in front of the backlight along a viewing direction, wherein the color filter includes a plurality of pixels repeating at a first spacing along a first axis. The apparatus further includes a lenticular layer disposed in front of the backlight, the lenticular layer including a section of material having a first index of refraction, a first, substantially flat side, and a second side defining a lenticularly patterned cross section along the first axis, the lenticularly patterned cross section including lens elements repeating at a second spacing and directing light originating from the backlight in two or more directions.

A method of rendering content for display on a multi-view display includes assigning a first display to a first pixel of a pixelated array, with a plurality of pixels periodically spaced along a first axis, the first display associated with a first viewing angle relative to the first axis. The method includes assigning a second display to a second pixel of the pixelated array, display associated with a second viewing angle relative to the first axis. The method further includes controlling a filter value of the first pixel based on a rendering of first content for display, and controlling a filter value of the second pixel based on a rendering of second content for display. The first viewing angle belongs to a first range of viewing angles of an optical multiplexer disposed in front of the pixelated array.

An ophthalmic device includes an enclosure, two immiscible fluids, an electrode, a dielectric, and an anion getter material. The enclosure is configured to mount on or in an eye of a user. The two immiscible fluids, including a first fluid and a second fluid, are disposed within the enclosure. The electrode is separated from the two immiscible fluids by the dielectric. The electrode is capable of forming a barrier layer during an anodization process when a voltage is applied across the electrode and the first fluid. The anion getter material is disposed within the ophthalmic device and is capable of gettering anion contaminants that inhibit the anodization process from forming the barrier layer.

A liquid crystal lens, a manufacturing method thereof, and a display device are disclosed. The liquid crystal lens includes a liquid layer located between a first substrate and a second substrate, the liquid layer includes a liquid crystal layer and a filler layer, the filler layer is filled in a square between the first substrate and the second substrate except the liquid crystal layer; the liquid crystal layer is made of a material different from the filler layer.

An optical system comprising: an optical element having an optical property responsive to an applied signal, a variation of the optical property with the signal exhibiting hysteresis in a first range of values and no hysteresis in a second range of values of the signal; a memory storing data representing a hysteresis curve which indicates the variation of the optical property with increasing and decreasing values of the signal; and a controller which continuously controls the optical property by: generating, based on the stored data, a cyclic signal having a discontinuity in each cycle of the cyclic signal, and setting the discontinuity size in each cycle based on the stored data such that a part of the variation of the optical property with the cyclic signal coincides with a part of the variation represented by the stored data; and applying the cyclic signal to the optical element.

An electrowetting display device includes a first support plate and a plurality of pixel walls on the first support plate. The plurality of pixel walls are associated with an electrowetting pixel. A pixel electrode is on the first support plate for applying a voltage within the electrowetting pixel. The device includes a second support plate over the first support plate, an organic layer on the second support plate, and an electrode layer on the organic layer. The electrode layer is patterned to include an opening. A pixel spacer is coupled to the second support plate. The pixel spacer includes a first portion in direct contact with the organic layer through the opening in the electrode layer. The pixel spacer is in contact with at least one pixel wall in the plurality of pixel walls.

A method and corresponding optical device to correct spherical aberration in an optical path caused by an electrically tunable lens (ETL) within the optical path. The method includes placing within the optical path and in working relationship with the ETL an aspherical correction lens dimensioned and configured to reduce spherical aberration in a light beam exiting the ETL.