Abstract: An electro-optical module assembly is provided that includes a flexible substrate having a first surface and a second surface opposite the first surface, wherein the flexible substrate contains an opening located therein that extends from the first surface to the second surface. An optical component is located on the second surface of the flexible substrate and is positioned to have a surface exposed by the opening. At least one electronic component is located on a first portion of the first surface of the flexible substrate, and at least one micro-energy source is located on a second portion of the first surface of the flexible substrate.

Abstract: A delivery device including a substrate formed in a coil comprising a plurality of loops, an active agent deposited between an inner surface and an outer surface of the substrate formed in the coil, and a pair of end caps, each end cap disposed on a corresponding end of the coil.

Abstract: Deep via technology is used to construct an integrated silicon cantilever and cavity oriented in a vertical plane which creates an electrostatically-switched MEMS switch in a small wafer area. Another embodiment is a small wafer area electrostatically-switched, vertical-cantilever MEMS switch wherein the switch cavity is etched within a volume defined by walls grown internally within a silicon substrate using through vias.

Abstract: A battery structure includes an anode packaging material having a first textured surface and an anode metal formed on the first textured surface. A separator is formed on the anode metal. A cathode packaging material includes a second textured surface. A cathode metal is formed on the second textured surface. An active cathode paste is formed on the cathode metal and brought into contact with the separator such that any gap is filled with electrolyte.

Abstract: A switching power supply in an integrated circuit, an integrated circuit comprising a switching power supply, and a method of assembling a switching power supply in an integrated circuit are disclosed. In one embodiment, the invention provides a three-dimensional switching power supply in an integrated circuit comprising a device layer. The switching power supply comprises three distinct strata arranged in series with the device layer, the three distinct strata including a switching layer including switching circuits, a capacitor layer including banks of capacitors, and an inductor layer including inductors. This switching power supply further comprises a multitude of connectors electrically and mechanically connecting together the device layer, the switching layer, the capacitor layer, and the inductor layer. The switching circuits, the capacitors and the inductors form a switching power supply for supplying power to the device layer.

Abstract: A mechanism is provided for an integrated laminated magnetic device. A substrate and a multilayer stack structure form the device. The multilayer stack structure includes alternating magnetic layers and diode structures formed on the substrate. Each magnetic layer in the multilayer stack structure is separated from another magnetic layer in the multilayer stack structure by a diode structure.

Abstract: An electronic package apparatus is formed from a semiconductor substrate having a cavity formed therein. The cavity has a top surface, a bottom surface and a sidewall surface, and a spacer extending from the bottom surface to the top surface. The spacer is formed from a dielectric material and has at least one lateral dimension less than 0.1 cm.

Abstract: A method of forming a flexible microbattery and battery is provided. The method including: forming a film with a cavity therein; applying a first outer flexible substrate to a first side of the film; applying a second outer flexible substrate to a second opposite side of the film, wherein a cathode, an anode, a separator and an electrolyte are located within the cavity and the film provides a first seal about the cathode, the anode, the separator and the electrolyte and wherein the first seal extends between the first outer flexible substrate and the second outer flexible substrate; cutting a trench through the first outer flexible substrate, the film and the second outer flexible substrate after the first seal is formed; disposing a curable material in the trench; curing the curable material to provide a second seal, wherein the first seal is located between the cavity and the second seal.

Abstract: A laminating structure includes a first magnetic layer, a second magnetic layer, a first spacer disposed between the first and second magnetic layers and a second spacer disposed on the second magnetic layer.

Abstract: A laminating structure includes a first magnetic layer, a second magnetic layer, a first spacer disposed between the first and second magnetic layers and a second spacer disposed on the second magnetic layer.

Abstract: Deep via technology is used to construct an integrated silicon cantilever and cavity oriented in a vertical plane which creates an electrostatically-switched MEMS switch in a small wafer area. Another embodiment is a small wafer area electrostatically-switched, vertical-cantilever MEMS switch wherein the switch cavity is etched within a volume defined by walls grown internally within a silicon substrate using through vias.

Abstract: A switching power supply in an integrated circuit, an integrated circuit comprising a switching power supply, and a method of assembling a switching power supply in an integrated circuit are disclosed. In one embodiment, the invention provides a three-dimensional switching power supply in an integrated circuit comprising a device layer. The switching power supply comprises three distinct strata arranged in series with the device layer, the three distinct strata including a switching layer including switching circuits, a capacitor layer including banks of capacitors, and an inductor layer including inductors. This switching power supply further comprises a multitude of connectors electrically and mechanically connecting together the device layer, the switching layer, the capacitor layer, and the inductor layer. The switching circuits, the capacitors and the inductors form a switching power supply for supplying power to the device layer.

Abstract: A digital biomedical device includes a substrate forming a reservoir, a membrane comprising a first layer and a second layer having a strain therebetween, the membrane sealing the reservoir, and a controller configured to activate the membrane and release at least a portion of the strain causing the membrane curl and open the reservoir.

Abstract: A digital biomedical device includes a substrate forming a cavity, a seal formed around the cavity, a lid coupled to the substrate by the seal, a reactive metal structure comprising a plurality of metal layers, wherein the reactive metal structure is a component of at least one of the substrate and the lid, a metal trace configured to initiate a self-propagating reaction between the plurality of metal layers of the reactive metal structure and release contents of the cavity, and a power supply configured to apply an electric current to the metal trace

Abstract: A switching power supply in an integrated circuit, an integrated circuit comprising a switching power supply, and a method of assembling a switching power supply in an integrated circuit are disclosed. In one embodiment, the invention provides a three-dimensional switching power supply in an integrated circuit comprising a device layer. The switching power supply comprises three distinct strata arranged in series with the device layer, the three distinct strata including a switching layer including switching circuits, a capacitor layer including banks of capacitors, and an inductor layer including inductors. This switching power supply further comprises a multitude of connectors electrically and mechanically connecting together the device layer, the switching layer, the capacitor layer, and the inductor layer. The switching circuits, the capacitors and the inductors form a switching power supply for supplying power to the device layer.

Abstract: A mechanism is provided for an integrated laminated magnetic device. A substrate and a multilayer stack structure form the device. The multilayer stack structure includes alternating magnetic layers and diode structures formed on the substrate. Each magnetic layer in the multilayer stack structure is separated from another magnetic layer in the multilayer stack structure by a diode structure.

Abstract: A magnetic device according to one embodiment includes a source of flux and a magnetic yoke coupled to the source of flux. The source of flux includes a thin film coil having multiple turns. The magnetic yoke has a pole with two or more gaps, wherein the coil turns have a non-uniform placement in the magnetic yoke for creating a higher magnetic field at one of the gaps than another of the gaps during writing. A magnetic device according to another embodiment includes a source of flux. A geometry of the magnetic pole near or at one of the gaps is different than a geometry of the magnetic pole near or at another of the gaps to help equalize fields formed at the gaps when the source of flux is generating flux.

Abstract: A laminating structure includes a first magnetic layer, a second magnetic layer, a first spacer disposed between the first and second magnetic layers and a second spacer disposed on the second magnetic layer.

Abstract: A volumetric integrated circuit manufacturing method is provided. The method includes assembling a slab element of elongate chips, exposing a wiring layer between adjacent elongate chips of the slab element, metallizing a surface of the slab element at and around the exposed wiring layer to form a metallized surface electrically coupled to the wiring layer and passivating the metallized surface to hermetically seal the metallized surface.

Abstract: A microbattery structure for hermetically sealed microbatteries is provided. In one embodiment, the microbattery structure includes a first silicon substrate containing at least one pedestal which houses a cathode material of a microbattery and at least one depression which houses A FIRST sealant material of the microbattery. The structure further includes a second silicon substrate containing at least one pedestal which houses an anode material of the microbattery and at least one depression which houses a second sealant material of the microbattery. An insulated centerpiece is bonded to the first sealant material present in at least two depressions on the first silicon substrate. An interlock structure is formed by aligning and superimposing the second silicon substrate on the first silicon substrate in a mortise and tenon fashion and sealing the two substrates using a high force.