In one embodiment, a biasing device is actuated using an actuator which is aligned with the biasing device along an alignment axis. A first frame is thereby biased toward a second frame along the alignment axis to bias an integrated circuit package toward a socket. The actuator also latches the first and second frames together and biased towards each other with the integrated circuit package and the socket biased toward each other. Other aspects and features are also described.

Disclosed are appendage mountable electronic systems and related methods for covering and conforming to an appendage surface. A flexible or stretchable substrate has an inner surface for receiving an appendage, including an appendage having a curved surface, and an opposed outer surface that is accessible to external surfaces. A stretchable or flexible electronic device is supported by the substrate inner and/or outer surface, depending on the application of interest. The electronic device in combination with the substrate provides a net bending stiffness to facilitate conformal contact between the inner surface and a surface of the appendage provided within the enclosure. In an aspect, the system is capable of surface flipping without adversely impacting electronic device functionality, such as electronic devices comprising arrays of sensors, actuators, or both sensors and actuators.

An assembly machine includes a plurality of track modules, each track module including a section of track, the plurality of track modules connectable to form a continuous circuitous track, the continuous circuitous track configured to receive a dispensing head, the dispensing head configured to rotate about the continuous circuitous track and at least partially assemble an unfinished product. The machine includes a first feeder module attached to a first length of the continuous circuitous track configured to feed a component to the dispensing head, and a first placement module attached to a second length of the continuous circuitous track configured to receive the unfinished product. The dispensing head is configured to place the component on the unfinished product. The assembly machine is reconfigurable by attaching or removing one or more of the plurality of track modules, the first feeder module and the first placement module.

Provided are a metal foil single-clad two-ply laminate which comprises two pairs of structures each comprising one prepreg or a laminate of two or more prepregs cladded with a metal foil on one surface thereof, wherein the two pairs of structures are laminated on each other through thermal compression via a release material put therebetween so that each prepreg faces inward, and wherein the release material is a film of a resin material or the like and its thickness is from 10 to 200 m, and the thermal shrinkage of the release material at the temperature of the thermal compression treatment is at most 1.5%; and a method for producing the laminate. Also disclosed are a single-sided printed wiring board and its production method using the metal foil single-clad two-ply laminate.

The present invention relates to a method for providing a reflective coating to a substrate for a light-emitting device, comprising the steps of: providing a substrate having a first surface portion with a first surface material and a second surface portion with a second surface material different from the first surface material; applying a reflective compound configured to attach to said first surface material to form a bond with the substrate in the first surface portion that is stronger than a bond between the reflective compound and the substrate in the second surface portion; curing said reflective compound to form a reflective coating having said bond between the reflective coating and the substrate in the first surface portion; and subjecting said substrate to a mechanical treatment with such an intensity as to remove said reflective coating from said second surface portion while said reflective coating remains on said first surface portion.

A cable (210) includes a center conductor (220). An insulating material in the form of a layer (225) surrounds the center conductor. A sparse shield (232) partially surrounds the insulating material. The sparse shield may include a plurality of conductors, which are grouped adjacent to one another within a space around the insulating layer that has a length that is less than 25% of the total circumference of the insulating layer. An insulating jacket (227) covers the sparse shield and the remainder of the cable. The cable may be used in a cable assembly (10).

A preassembled display system is assembled at a first location by attaching a plurality of display panels to a frame. The preassembled display system is loaded onto a transportation vehicle. Next, the preassembled display system is moved to a second location in a transportation vehicle. The display unit is installed at the second location by attaching the preassembled display system to a mounting unit. A receiver box for providing media to display at the plurality of display panels is attached. The attaching of the receiver box may be performed at the first location and/or at the second location. The plurality of display panels are electrically connected to the receiver box. Again, the electrically connecting may be performed at the first location and/or at the second location.

Corrosion Resistant Ozone Generators, including ozone generating chips, for various purposes including spas, pools and jetted tubs as well as methods for making and using such Corrosion Resistant Ozone Generators.

A surface position detection apparatus capable of highly precisely detecting the surface position of a surface to be detected without substantially being affected by relative positional displacement due to a polarization component occurring in a light flux having passed through a reflective surface. In the apparatus, a projection system has a projection side prism member having first reflective surfaces, and a light receiving system has a light receiving prism member having second reflective surfaces arranged in correspondence with the projection side prism member. The surface position detection apparatus further has a member for compensating relative positional displacement due to a polarization component of a light flux having passed through the first and second reflective surfaces.

A method of manufacturing a through-hole electrode substrate includes forming a plurality of through-holes in a substrate, forming a plurality of through-hole electrodes by filling a conductive material into the plurality of through-holes, forming a first insulation layer on one surface of the substrate, forming a plurality of first openings which expose the plurality of through-hole electrodes corresponding to each of the plurality of through-hole electrodes, on the first insulation layer and correcting a position of the plurality of first openings using the relationship between a misalignment amount of a measured distance value of an open position of a leaning through-hole among the plurality of through-holes and of a design distance value of the open position of the leaning through-hole among the plurality of through-holes with respect to a center position of the substrate.