Abstract: The invention discloses a vessel automatic berthing wireless charging integrated system and operating method thereof. The invention comprises a charging barge and at least one vessel. The charging barge comprises a power, a distribution board and a locking module control system, and every vessel comprises an automatic pilot system, a vessel controlling system and a wireless power receiving module. A bow berthing module of the present invention moors the vessel. After a guiding structure of the bow berthing module straightly aligns bow direction of the vessel, a wireless power supplying module of a side berthing module matches with the wireless power receiving module then charges the vessel.

Abstract: A semiconductor device includes a first fin, a second fin, and a third fin protruding above a substrate, where the third fin is between the first fin and the second fin; a gate dielectric layer over the first fin, the second fin, and the third fin; a first work function layer over and contacting the gate dielectric layer, where the first work function layer extends along first sidewalls and a first upper surface of the first fin; a second work function layer over and contacting the gate dielectric layer, where the second work function layer extends along second sidewalls and a second upper surface of the second fin, where the first work function layer and the second work function layer comprise different materials; and a first gate electrode over the first fin, a second gate electrode over the second fin, and a third gate electrode over the third fin.

Abstract: Devices with aluminum structures and methods of fabrication are provided. An exemplary device includes an interconnect structure and an aluminum structure electrically connected to the interconnect structure. The aluminum structure includes a first aluminum layer, a migration barrier layer over the first aluminum layer, and a second aluminum layer over the migration barrier layer.

Abstract: A semiconductor device includes a first fin, a second fin, and a third fin protruding above a substrate, where the third fin is between the first fin and the second fin; a gate dielectric layer over the first fin, the second fin, and the third fin; a first work function layer over and contacting the gate dielectric layer, where the first work function layer extends along first sidewalls and a first upper surface of the first fin; a second work function layer over and contacting the gate dielectric layer, where the second work function layer extends along second sidewalls and a second upper surface of the second fin, where the first work function layer and the second work function layer comprise different materials; and a first gate electrode over the first fin, a second gate electrode over the second fin, and a third gate electrode over the third fin.

Abstract: A waveguide structure includes a substrate and a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient. The waveguide structure also includes a first cladding layer at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient. The second cladding layer is coupled to the first cladding layer.

Abstract: A waveguide structure includes a substrate and a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient. The waveguide structure also includes a first cladding layer at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient. The second cladding layer is coupled to the first cladding layer.

Abstract: Microwave photonic devices use light to carry and process microwave signals over a photonic link. Light can be used as a stimulus to microwave devices that directly control microwave signals. Previous optically controlled devices suffer from large footprint, high optical power level required for switching, lack of scalability and complex integration requirements, restricting their implementation in practical microwave systems. Disclosed are monolithic optically reconfigurable integrated microwave switches (MORIMSs) built on a CMOS compatible silicon photonic chip. The disclosed scalable micrometer-scale switches provide higher switching efficiency and operate using optical power that is orders of magnitude lower than previous devices. The disclosed devices and techniques provide examples of silicon photonic platforms integrating microwave circuitry.

Abstract: An optical switch structure includes at least one optical input port and at least one optical output port. The optical switch structure also includes an optical waveguide structure including a waveguide core and a waveguide cladding The optical waveguide structure is optically coupled to the at least one optical input port and the at least one optical output port. The waveguide core includes a first material characterized by a first index of refraction and a first electro-optic coefficient and the waveguide cladding includes a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient.

Abstract: An optical switch structure includes a substrate, a first electrical contact, a first material having a first conductivity type electrically connected to the first electrical contact, a second material having a second conductivity type coupled to the first material, and a second electrical contact electrically connected to the second material. The optical switch structure also includes a waveguide structure disposed between the first electrical contact and the second electrical contact and comprising a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction and a second electro-optic.

Abstract: The invention discloses a vessel automatic berthing wireless charging integrated system and operating method thereof. The invention comprises a charging barge and at least one vessel. The charging barge comprises a power, a distribution board and a locking module control system, and every vessel comprises an automatic pilot system, a vessel controlling system and a wireless power receiving module. A bow berthing module of the present invention moors the vessel. After a guiding structure of the bow berthing module straightly aligns bow direction of the vessel, a wireless power supplying module of a side berthing module matches with the wireless power receiving module then charges the vessel.

Abstract: An optical switch structure includes a substrate, a first electrical contact, a first material having a first conductivity type electrically connected to the first electrical contact, a second material having a second conductivity type coupled to the first material, and a second electrical contact electrically connected to the second material. The optical switch structure also includes a waveguide structure disposed between the first electrical contact and the second electrical contact and comprising a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction and a second electro-optic.

Abstract: A full load test system of an electrical power converter and the test method thereof is disclosed. The full load test method of the electrical power converter comprises the following steps: (a) providing a power converter under test (PCUT); (b) configuring the PCUT in/on a test circuit; (c) serially connecting the PCUT with at least one bidirectional power converter in the test circuit; (d) connecting the test circuit to an alternating current low voltage three-phase power source; and (e) performing a test of the PCUT under full-load condition.

Abstract: The present invention discloses a vessel power safety control system and operating method thereof. The vessel power safety control system includes a load power management module, a real-time monitoring module, an integration module and a power module. The present invention can assist the autonomous ship as any occurrence of fault during navigation. Once the accident occurs, the load power management module will give an instruction to control the DC bus to switch from closed circuit to open circuit to protect other equipment. After determining whether the errors of the equipment on board is eliminated, the load power management system performs automatic system reset procedure. As such, the DC bus can be converted from an open circuit to a closed circuit to restart the power supply for the facility.

Abstract: An optical switch structure includes a substrate, a first electrical contact, a first material having a first conductivity type electrically connected to the first electrical contact, a second material having a second conductivity type coupled to the first material, and a second electrical contact electrically connected to the second material. The optical switch structure also includes a waveguide structure disposed between the first electrical contact and the second electrical contact and comprising a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction and a second electro-optic.

Abstract: An optical switch structure includes a substrate, a first electrical contact, and a first material having a first conductivity type electrically connected to the first electrical contact. The optical switch structure also includes a second material having a second conductivity type coupled to the first material, a second electrical contact electrically connected to the second material, and a waveguide structure disposed between the first electrical contact and the second electrical contact. The waveguide structure includes a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient.

Abstract: Microwave photonic devices use light to carry and process microwave signals over a photonic link. Light can be used as a stimulus to microwave devices that directly control microwave signals. Previous optically controlled devices suffer from large footprint, high optical power level required for switching, lack of scalability and complex integration requirements, restricting their implementation in practical microwave systems. Disclosed are monolithic optically reconfigurable integrated microwave switches (MORIMSs) built on a CMOS compatible silicon photonic chip. The disclosed scalable micrometer-scale switches provide higher switching efficiency and operate using optical power that is orders of magnitude lower than previous devices. The disclosed devices and techniques provide examples of silicon photonic platforms integrating microwave circuitry.

Abstract: An optical switch structure includes a substrate, a first electrical contact, and a first material having a first conductivity type electrically connected to the first electrical contact. The optical switch structure also includes a second material having a second conductivity type coupled to the first material, a second electrical contact electrically connected to the second material, and a waveguide structure disposed between the first electrical contact and the second electrical contact. The waveguide structure includes a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient.

Abstract: A full load test system of an electrical power converter and the test method thereof is disclosed. The full load test method of the electrical power converter comprises the following steps: (a) providing a power converter under test (PCUT); (b) configuring the PCUT in/on a test circuit; (c) serially connecting the PCUT with at least one bidirectional power converter in the test circuit; (d) connecting the test circuit to an alternating current low voltage three-phase power source; and (e) performing a test of the PCUT under full-load condition.

Abstract: An optical switch structure includes a substrate, a first electrical contact, and a first material having a first conductivity type electrically connected to the first electrical contact. The optical switch structure also includes a second material having a second conductivity type coupled to the first material, a second electrical contact electrically connected to the second material, and a waveguide structure disposed between the first electrical contact and the second electrical contact. The waveguide structure includes a waveguide core coupled to the substrate and including a first material characterized by a first index of refraction and a first electro-optic coefficient and a waveguide cladding at least partially surrounding the waveguide core and including a second material characterized by a second index of refraction less than the first index of refraction and a second electro-optic coefficient greater than the first electro-optic coefficient.

Abstract: An energy management strategy for boats and ships is provided. The aforementioned strategy comprises a strategy for low-load conditions and a strategy for high-load conditions, specifically for the sailing conditions of boats and ships. The output and distribution of energy are dynamically adjusted in accordance with commands, tides, time, locations, weather, hydrologic conditions and other factors may impact the sailing, in order to optimize the energy efficiency of boats and ships.