Abstract: A system for simultaneous multiple point of view video is disclosed. The system may receive a first video stream from a first device, receive a second video stream from a second device, and receive a third video stream from a third device, extract timing data from each of the first video stream, the second video stream, and the third video stream, determine time signatures associated with each of the first video stream, the second video stream, and the third video stream based on the timing data, generate a post-process data based on each of the first video stream, the second video stream, and the third video stream, and align one or more time signatures encoded on the post-process data to generate a production data file comprising a plurality of time synchronized video streams corresponding to each of the first video stream, the second video stream, and the third video stream.

Abstract: An (A) additive organopolysiloxane composition is disclosed which comprises (A1) a branched organopolysiloxane polymer comprising M, D and Q siloxy units and (A2) a silicone resin. The (A) additive organopolysiloxane composition has a content of aliphatically unsaturated groups of from 1.5 to 7.0 wt. %. A curable composition is also disclosed, the curable composition comprising the (A) additive organopolysiloxane composition, (B) an organosilicon compound having at least two silicon-bonded hydrogen atoms per molecule, and (C) a hydrosilylation catalyst. A method of preparing the curable and a method of forming a film with the curable composition are also disclosed.

Abstract: An (A) additive organopolysiloxane composition is disclosed which comprises (A1) a branched organopolysiloxane polymer comprising M, D and Q siloxy units and (A2) a silicone resin. The (A) additive organopolysiloxane composition has a content of aliphatically unsaturated groups of from 1.5 to 7.0 wt. %. A curable composition is also disclosed, the curable composition comprising the (A) additive organopolysiloxane composition, (B) an organosilicon compound having at least two silicon-bonded hydrogen atoms per molecule, and (C) a hydrosilylation catalyst. A method of preparing the curable and a method of forming a film with the curable composition are also disclosed.

Abstract: Supercapacitor structures are provided which include, for example: one or more layers of supercapacitors; and one or more contact tabs. The one or more contact tabs electrically contact and extend outward from the supercapacitor structure to facilitate electrical connection to the supercapacitor structure, and the one or more contact tabs include a multi-contact tab. The multi-contact tab is configured and sized with multiple contact locations which are disposed external to the supercapacitor structure. Various supercapacitor structures are provided, including one supercapacitor structure with a shared C-shaped current collector, and another supercapacitor structure with stacked supercapacitors. One or more additional multi-contact tabs may also extend from the supercapacitor structure(s) and distribute the same or a different capacitor voltage than the multi-contact tab.

Abstract: Energy storage structures and fabrication methods are provided. The method include: providing first and second conductive sheet portions separated by a permeable separator sheet, and defining, at least in part, outer walls of the energy storage structure, the first and second surface regions of the first and second conductive sheet portions including first and second electrodes facing first and second (opposite) surfaces of the permeable separator sheet; forming an electrolyte receiving chamber, defined, at least in part, by the first and second surface regions, including: bonding the first and second conductive sheet portions, and the permeable separator sheet together with at least one bonding border forming a bordering frame around at least a portion of the first and second electrodes; and providing an electrolyte within the electrolyte receiving chamber, including in contact with the first and second electrodes, with the electrolyte being capable of passing through the permeable separator sheet.

Abstract: Ultra-capacitor structures and electronic systems and assemblies are provided. In one aspect, the ultra-capacitor structure is configured to selectively power and at least partially house electronic component(s) therein. In one embodiment, the ultra-capacitor structure includes a thermally conductive material facilitating dissipation of heat generated. In another embodiment, the ultra-capacitor structure includes an electrically conductive sheet facilitating electromagnetic shielding. In another aspect, an electronic system includes: an electronic device including electronic component(s); and a support structure physically receiving and electrically coupling to the electronic device, and including an ultra-capacitor structure configured to selectively power the electronic component(s) of the electronic device when electrically coupled to the support structure.

Abstract: Supercapacitor structures are provided which include, for example: one or more layers of supercapacitors; and one or more contact tabs. The one or more contact tabs electrically contact and extend outward from the supercapacitor structure to facilitate electrical connection to the supercapacitor structure, and the one or more contact tabs include a multi-contact tab. The multi-contact tab is configured and sized with multiple contact locations which are disposed external to the supercapacitor structure. Various supercapacitor structures are provided, including one supercapacitor structure with a shared C-shaped current collector, and another supercapacitor structure with stacked supercapacitors. One or more additional multi-contact tabs may also extend from the supercapacitor structure(s) and distribute the same or a different capacitor voltage than the multi-contact tab.

Abstract: Ultra-capacitor structures and electronic systems and assemblies are provided. In one aspect, the ultra-capacitor structure is configured to selectively power and at least partially house electronic component(s) therein. In one embodiment, the ultra-capacitor structure includes a thermally conductive material facilitating dissipation of heat generated. In another embodiment, the ultra-capacitor structure includes an electrically conductive sheet facilitating electromagnetic shielding. In another aspect, an electronic system includes: an electronic device including electronic component(s); and a support structure physically receiving and electrically coupling to the electronic device, and including an ultra-capacitor structure configured to selectively power the electronic component(s) of the electronic device when electrically coupled to the support structure.

Abstract: Supercapacitor structures are provided which include, for example: one or more layers of supercapacitors; and one or more contact tabs. The one or more contact tabs electrically contact and extend outward from the supercapacitor structure to facilitate electrical connection to the supercapacitor structure, and the one or more contact tabs include a multi-contact tab. The multi-contact tab is configured and sized with multiple contact locations which are disposed external to the supercapacitor structure. Various supercapacitor structures are provided, including one supercapacitor structure with a shared C-shaped current collector, and another supercapacitor structure with stacked supercapacitors. One or more additional multi-contact tabs may also extend from the supercapacitor structure(s) and distribute the same or a different capacitor voltage than the multi-contact tab.

Abstract: Energy devices with ultra-capacitor structures and methods thereof are presented. The energy devices include, for example: an ultra-capacitor structure having a power input terminal; and a battery structure electrically connected to the ultra-capacitor structure via a switching element, the switching element being selectively controllable between a first state and a second state, wherein the first state functions as a pass through to electrically connect the battery structure to the power input terminal of the ultra-capacitor structure, and the second state functions to electrically isolate the battery structure from the power input terminal of the ultra-capacitor structure. The methods include: selectively charging the battery structure through the ultra-capacitor structure using at least a portion of the electrical power provided to the power input terminal thereof.

Abstract: Ultra-capacitor structures and methods thereof are presented. In one aspect, a structure includes: an ultra-capacitor structure having multiple ultra-capacitor cells; and a switching mechanism, the switching mechanism being operable to selectively connect different electrical interconnect configurations of the multiple ultra-capacitor cells of the ultra-capacitor structure to provide any one of a plurality of different voltages or currents to at least one electrical load, and to selectively control charging of the multiple ultra-capacitor cells using energy from at least one battery. In another aspect, a method includes: obtaining an ultra-capacitor structure having multiple ultra-capacitor cells; connecting different electrical interconnect configurations of the multiple ultra-capacitor cells of the ultra-capacitor structure to provide any one of a plurality of different voltages or currents to at least one electrical load; and charging the ultra-capacitor structure using energy from at least one battery.

Abstract: Ultra-capacitor structures and electronic systems and assemblies are provided. In one aspect, the ultra-capacitor structure is configured to selectively power and at least partially house electronic component(s) therein. In one embodiment, the ultra-capacitor structure includes a thermally conductive material facilitating dissipation of heat generated. In another embodiment, the ultra-capacitor structure includes an electrically conductive sheet facilitating electromagnetic shielding. In another aspect, an electronic system includes: an electronic device including electronic component(s); and a support structure physically receiving and electrically coupling to the electronic device, and including an ultra-capacitor structure configured to selectively power the electronic component(s) of the electronic device when electrically coupled to the support structure.

Abstract: Energy storage structures and fabrication methods are provided. The method include: providing first and second conductive sheet portions separated by a permeable separator sheet, and defining, at least in part, outer walls of the energy storage structure, the first and second surface regions of the first and second conductive sheet portions including first and second electrodes facing first and second (opposite) surfaces of the permeable separator sheet; forming an electrolyte receiving chamber, defined, at least in part, by the first and second surface regions, including: bonding the first and second conductive sheet portions, and the permeable separator sheet together with at least one bonding border forming a bordering frame around at least a portion of the first and second electrodes; and providing an electrolyte within the electrolyte receiving chamber, including in contact with the first and second electrodes, with the electrolyte being capable of passing through the permeable separator sheet.

Abstract: Supercapacitor structures are provided which include, for example: one or more layers of supercapacitors; and one or more contact tabs. The one or more contact tabs electrically contact and extend outward from the supercapacitor structure to facilitate electrical connection to the supercapacitor structure, and the one or more contact tabs include a multi-contact tab. The multi-contact tab is configured and sized with multiple contact locations which are disposed external to the supercapacitor structure. Various supercapacitor structures are provided, including one supercapacitor structure with a shared C-shaped current collector, and another supercapacitor structure with stacked supercapacitors. One or more additional multi-contact tabs may also extend from the supercapacitor structure(s) and distribute the same or a different capacitor voltage than the multi-contact tab.

Abstract: An attachment for a fuel tank of a fuel cell powered system is described. The attachment thermally conducts heat generated from an electronic component to the fuel tank. The attachment further affixes to the electronic component by a securing portion. In one aspect, the attachment is comprised in a fuel cell powered electronic device. In another aspect, the attachment is integral to the fuel tank.

Abstract: An attachment for a fuel tank of a fuel cell powered system is described. The attachment thermally conducts heat generated from an electronic component to the fuel tank. The attachment further affixes to the electronic component by a securing portion. In one aspect, the attachment is comprised in a fuel cell powered electronic device. In another aspect, the attachment is integral to the fuel tank.