The present invention discloses a liquid crystal grating, a manufacturing method and a drive method thereof, and an optical phased array. In the liquid crystal grating, plurality of first electrodes are formed on a lower substrate with first gaps formed between adjacent first electrodes, second electrodes are further provided above the first gaps with second gaps formed between adjacent second electrodes, and an insulation layer is provided between the first electrodes and the second electrodes. When voltages are applied to the first electrodes and the second electrodes, continuously and smoothly changing electric field is generated inside the liquid crystal grating, and then phases of incident light may be controlled continuously and smoothly, which improves the ability of the liquid crystal grating to modulate light beam.

A cable attach structure for attaching a fiber-optic cable to a rear end and a connector to a front end is disclosed. In one embodiment, the cable attach structure is a portion of a fiber optic cable assembly having a fiber optic cable with at least one optical fiber and a connector attached to the optical fiber. The fiber optic cable is attached to the cable attach structure at a rear end and circuit board is attached to the cable attach structure at the front end. The cable attach structure also routes the at least one optical fiber away from the centerline of the connector for off-axis fiber routing. In other embodiments, the optical fiber can enter the connector from a first direction and attach to the connector in a second direction if desired.

The present disclosure provides a touch panel, including: a substrate having a visible region and a non-visible region adjacent to at least one side of the visible region; a composite layer disposed over the non-visible region, wherein the composite layer includes a color layer and a light-shielding layer, and the color layer is disposed between the substrate and the light-shielding layer, wherein a side of the color layer adjacent to the visible region has a first inclined surface, and a side of the light-shielding layer adjacent to the visible region has a second inclined surface, wherein the first inclined surface and the second inclined surface are form a continuous surface; a sensing layer disposed over the visible region and extending to a portion of the non-visible region, wherein the sensing layer directly contacts the visible region of the substrate; and a signal wire disposed over the composite layer.

A method for manufacturing a wiring board includes preparing a large-sized wiring board having an effective region and a dummy region such that the board has a penetrating hole on a border of the effective and dummy regions and an inner-hole conductive layer covering an inner surface of the penetrating hole, moving a rotary tool having a tip blade along rotation axis at a peripheral portion of the penetrating hole such that the rotary tool drills a hole into the board at the peripheral portion and segments the conductive layer into portions in the effective and dummy regions, and moving a rotary tool having a side blade in a direction perpendicular to rotation axis such that the dummy region is cut off from the effective region after the rotary tool having tip blade makes the hole and a wiring board having the effective region of the board is formed.

Systems and methods of manufacturing printed circuit boards using blind and internal micro vias to couple subassemblies. An embodiment of the invention provides a method of manufacturing a printed circuit including attaching a plurality of metal layer carriers to form a first subassembly including at least one copper foil pad on a first surface, applying an encapsulation material onto the first surface of the first subassembly, curing the encapsulation material and the first subassembly; applying a lamination adhesive to a surface of the cured encapsulation material, forming at least one via in the lamination adhesive and the cured encapsulation material to expose the at least one copper foil pad, attaching a plurality of metal layer carriers to form a second subassembly, and attaching the first subassembly and the second subassembly.

Roll-to-roll processes for manufacturing touch sensors on a plastic base film are provided. The touch sensors can be deposited on the base film using various patterning techniques. One or more shorting bars can also be patterned onto the base film to couple together traces, such as drive lines, sense lines, conductive traces, and the like, of the touch sensor to prevent a potential difference from forming between traces due to static buildup during the manufacturing process. After the touch sensor is fully formed on the base film, the touch sensor can be removed from the base film using lithography or a physical cutting process. The removal process can separate the touch sensor from the one or more shorting bars, thereby uncoupling the traces of the touch sensor.

Methods and systems for manufacturing a swallowable sensor device are disclosed. Such a method includes mechanically coupling a plurality of internal components, wherein the plurality of internal components includes a printed circuit board having a plurality of projections extending radially outward. A cavity is filled with a potting material, and the mechanically coupled components are inserted into the cavity. The cavity may be pre-filled with the potting material, or may be filled after the mechanically coupled components have been inserted therein. A distal end of each projection abuts against a wall of the cavity thereby preventing the potting material from covering each distal end. The cavity is sealed with a cap causing the potting material to harden within the sealed cavity to form a housing of the swallowable sensor device, wherein the distal end of each projection is exposed to an external environment of the swallowable sensor device.

Electrified access-control technology devices for a door, particularly electrified locks for a door, having embedded circuitry therein, and methods of making the same. One or more printed circuit boards (PCBs) having various electronic circuitry are secured inside a housing that encases an access-control device, particularly a lock, for a door. The one or more PCB(s) may be embedded on an internal surface of the housing such that the embedded PCB resides inside the housing along with the lock itself. The embedded PCB(s) avoid interference of both any working components of the lock inside the housing and any openings residing in the housing.

A method for connecting a differential transmission cable, (and a differential transmission cable and an electric device) includes: connecting a pair of conductors for transmitting a differential signal to transceivers; and connecting a second shield provided on the periphery of a first shield via an insulating layer to frame grounds, without electrically connecting anywhere the first shield that is provided on the periphery of the pair of conductors via a dielectric layer.

Surface mount components and related methods involve thin film circuits between first and second insulating substrates. The thin film circuits may include passive components, including resistors, capacitors, inductors, arrays of such components, networks, or filters of multiple passive components. Such thin film circuit(s) can be sandwiched between first and second insulating substrates with internal conductive pads which are exposed to the outside of the surface mount component and electrically connected to external terminations. External terminations may include at least one layer of conductive polymer. Optional shield layers may protect the surface mount components from signal interference. A cover substrate may be formed with a plurality of conductive elements that are designed to generally align with the conductive pads such that conductive element portions are exposed in groups along surfaces of a device.