A display device includes a first substrate and a pixel electrode on the first substrate. A thickness of the pixel electrode is about 40 nanometers (nm) or less.

Sensors incorporating piezoresistive materials are described. One class of includes conductive traces formed directly on or otherwise integrated with the piezoresistive material.

Microfluidic structures featuring substantially circular channels may be fabricated by embossing polymer sheets.

A method of forming a flexible interconnect circuit is described. The method may comprise laminating a substrate to a conductive layer and patterning the conductive layer using a laser while the conductive layer remains laminated to the substrate thereby forming a first conductive portion and a second conductive portion of the conductive layer. The substrate maintains the orientation of the first conductive portion relative to the second conductive portion during and after patterning. The method may also comprise laminating a first insulator to the conductive layer and removing the substrate from the conductive layer such that the first insulator maintains the orientation of the first conductive portion relative to the second conductive portion while and after the substrate is removed. The method may also comprise laminating a second insulator to the second side of the conductive layer while the first insulator remains laminated to the substrate.

A flexible circuit electrode array with more than one layer of metal traces comprising: a polymer base layer; more than one layer of metal traces, separated by polymer layers, deposited on the polymer base layer, including electrodes suitable to stimulate neural tissue; and a polymer top layer deposited on the polymer base layer and the metal traces. Polymer materials are useful as electrode array bodies for neural stimulation. They are particularly useful for retinal stimulation to create artificial vision, cochlear stimulation to create artificial hearing, or cortical stimulation many purposes. The pressure applied against the retina, or other neural tissue, by an electrode array is critical. Too little pressure causes increased electrical resistance, along with electric field dispersion. Too much pressure may block blood flow.

A laminate contains conductive circuit patterns, a substrate material, and an adhesive pattern or other bond. Each conductive circuit pattern and the substrate material are interconnected by the adhesive pattern or other bond, having its size and shape substantially matching the main outlines of each conductive circuit pattern. Each conductive circuit pattern has thin lines and thin interline spaces, patterned on top of the adhesive pattern or other bond by a removal of conductive material, such that the circuit pattern's thin interline spaces may have residues of the adhesive patterns or other bond. Outside the conductive circuit patterns' main outlines, the substrate material is substantially void of an adhesive or other bond, with the exception of edge areas of the main outlines.

An apparatus and method wherein the apparatus comprises; a flexible display; a flexible touch sensitive module; and a first flexible coating overlaying the flexible display and a second flexible coating overlaying the touch sensitive module; wherein at least a portion of the touch sensitive module is mounted on the first flexible coating.

Provided are interconnect circuits and methods of forming thereof. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.

A manufacturing method of a redistribution layer is provided. The method includes the following steps. A patterned sacrificial layer is formed on a carrier. An actuate angle is formed between a side wall of the patterned sacrificial layer and the carrier. A first conductive layer is formed. The first conductive layer includes a plurality of first portions formed on the carrier and a plurality of second portions formed on the patterned sacrificial layer. The patterned sacrificial layer and the second portions of the first conductive layer are removed from the carrier. Another manufacturing method of a redistribution layer is also provided.

A method of forming a flexible interconnect circuit is described. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.