Abstract: A coating for an optical article, such as a lens, includes a bottom coating having at least one hydrophilic resin binder and at least one surfactant, forming an anti-fogging layer, and a top coating overlying the bottom coating, forming an anti-reflective layer. The top coating includes nanopores, which may be less than 150 nm in size.

Abstract: A coating for an optical article, such as a lens, includes a bottom coating having at least one hydrophilic resin binder and at least one surfactant, forming an anti-fogging layer, and a top coating overlying the bottom coating, forming an anti-reflective layer. The top coating includes nanopores, which may be less than 150 nm in size.

Abstract: A coating for an optical article, such as a lens, includes a bottom coating having at least one hydrophilic resin binder and at least one surfactant, forming an anti-fogging layer, and a top coating overlying the bottom coating, forming an anti-reflective layer. The top coating includes nanopores, which may be less than 150 nm in size.

Abstract: Optical Position Encoders and methods using the same are described. In embodiments, the optical position encoders include a multitrack Hybrid Cyclic Binary Code-2 (HCBC-2) encoded scale and an Optical Readout Assembly (ORA), where the ORA provides absolute position optical readout and automatic physical alignment to the scale. Linear optical position encoders, rotary optical position encoders, and methods of measuring the position of ORA relative to a scale using such encoders are also described.

Abstract: Optical Position Encoders and methods using the same are described. In embodiments, the optical position encoders include a multitrack Hybrid Cyclic Binary Code-2 (HCBC-2) encoded scale and an Optical Readout Assembly (ORA), where the ORA provides absolute position optical readout and automatic physical alignment to the scale. Linear optical position encoders, rotary optical position encoders, and methods of measuring the position of ORA relative to a scale using such encoders are also described.

Abstract: Technologies for determining positional coordinates on the surface of an object are disclosed. In some embodiments the technologies utilize a code drum to encode incident light into structured light and non-structured light that is projected on the surface of the object being measured. The code drum may include a plurality of hybrid cyclic binary code (HCBC) patterns, wherein the plurality of HCBC patterns include a plurality of weighted numbering system patterns, and a plurality of unweighted numbering system patterns. Systems and methods for measuring positional coordinates on a surface of an object being measured are also described.

Abstract: A coating for an optical article, such as a lens, includes a bottom coating having at least one hydrophilic resin binder and at least one surfactant, forming an anti-fogging layer, and a top coating overlying the bottom coating, forming an anti-reflective layer. The top coating includes nanopores, which may be less than 150 nm in size.

Abstract: Technologies for determining positional coordinates on the surface of an object are disclosed. In some embodiments the technologies utilize a code drum to encode incident light into structured light and non-structured light that is projected on the surface of the object being measured. The code drum may include a plurality of hybrid cyclic binary code (HCBC) patterns, wherein the plurality of HCBC patterns include a plurality of weighted numbering system patterns, and a plurality of unweighted numbering system patterns. Systems and methods for measuring positional coordinates on a surface of an object being measured are also described.

Abstract: Anti-reflective (AR) coatings and methods for applying AR coatings to substrates, such as optical lenses. The coating may include a polyurethane base layer and a fluoropolymer top layer. The base layer may protect the underlying substrate, promote adhesion between the top layer and the underlying substrate, and achieve index-matching with the underlying substrate. The method may involve an inexpensive and efficient solution coating process.

Abstract: A pneumatically controlled, two part, rotational face seal is disclosed that has dual modes of operation. There is a first, static mode where a face of each of the two parts of the seal touch each other and provide an air, liquid and water vapor tight, very low leakage rate with high rotational friction between the two parts of the seal. In the second, dynamic mode wherein the two parts of the seal are separated by inert gas and the face seal functions as a gas bearing having very low rotational friction as the two parts are rotated with respect to each other. One part of the seal may be attached to a rotatable turret and the other part may be attached to a base on which the turret is mounted.

Abstract: A face shield assembly including a frame and a removable protective element supported by the frame is disclosed herein. The protective element is removably supported in an opening of the frame by a channel, without the use of fasteners. Because the face shield lacks fasteners, it is easy to remove and replace, even with the use of gloves. In one embodiment, the frame is molded as a single, unitary member and includes an upper detent, a lower detent and a channel formed between a lip and the frame that receives an edge of the protective element in order to hold the protective element within the frame. In another embodiment, the frame is pivotally supported on a support structure such that the frame can be moved between an upper (out of use) and a lower (in use) position, and may further include an adjustable mounting member so that the frame can be selectively spaced relative to the user's head.

Abstract: A deoxidizing liquid composition for aluminum contains in addition to water: fluoroborate anions, preferably from added fluoroboric acid; an acid, preferably nitric acid, that is a substantially stronger acid than either fluoroboric acid or boric acid; an additional oxidizing agent, preferably hydrogen peroxide; and an organic azole compound. Preferably the composition also contains propylene glycol, which is a stabilizer for hydrogen peroxide and also improves deoxidizing results.