{"@type": "dcat:Dataset", "accessLevel": "public", "bureauCode": ["019:20"], "contactPoint": {"@type": "vcard:Contact", "fn": "Chris Vermillion", "hasEmail": "mailto:cvermil@ncsu.edu"}, "dataQuality": true, "description": "This submission includes three peer-reviewed (under review) papers from the researchers at North Carolina State University presenting control-based techniques to maximize effectiveness of a tethered tidal kite. Below are the abstracts of each file included in the submission.\n\nCobb TCST - Iterative learning for kite path optimization.pdf\nThis paper presents an iterative learning control-based approach for optimizing the flight path geometry of a tethered MHK system. Tethered MHK systems, which replace the tower and turbine of a conventional system with a tether and a lifting body, capture energy by driving a generator with the tension in the tether. By spooling out tether during the high tension portions of cross-current flight and spooling in during low tension portions, net positive energy is generated over one cycle. Because the net energy generation is sensitive to the shape of the flown path, we employ an iterative learning update law to adapt the path shape from one lap to the next. Additionally, we present a realistic system model, along with lower-level path-following and power take-off (PTO) controllers. We then demonstrate the efficacy of our algorithm on this model in both uniform and realistic flow environments.\n\nSiddiqui ACC - Optimal spooling control of kites in variable flow.pdf\nThis work focuses on the development of an adaptive control strategy that fuses Gaussian process modeling and receding horizon control to ideally manage the tradeoff between exploration (i.e., maintaining an adequate map of the resource) and exploitation (i.e., carrying out a mission, which consists in this work of harvesting the resource). The use of a receding horizon formulation aids in the consideration of limited mobility, which is characteristic of dynamical systems. In this work, we focus on an airborne wind energy (AWE) system as a case study, where the system can vary its elevation angle (tether angle relative to the ground, which trades off higher efficiency with higher-altitude operation) and flight path parameters in order to maximize power output in a wind environment that is changing in space and time. We demonstrate the effectiveness of the proposed approach through a data-driven study on a rigid wing-based AWE system.\n\nReed ACC - Spatial optimization of kite paths.pdf\nThis paper presents a technique for maximizing the power production of a tethered marine energy-harvesting kite performing cross-current figure-eight flight in a 3D spatiotemporally varying flow environment. To generate a net positive power output, the kite employs a cyclic spooling method, where the kite is spooled out while flying in high-tension crosscurrent figure-eight flight, then spooled in radially towards the base-station under low tension.", "distribution": [{"@type": "dcat:Distribution", "accessURL": "https://mhkdr.openei.org/files/343/Cobb_TCST_2020_UNPUBLISHED.pdf", "description": "Cobb et al. peer-reviewed (under review) journal paper submitted to IEEE Transactions on Control Systems Technology (TCST). Focuses on applying iterative learning techniques to undersea kite path optimization.", "format": "pdf", "mediaType": "application/pdf", "title": "Cobb TCST - Iterative learning for kite path optimization.pdf"}, {"@type": "dcat:Distribution", "accessURL": "https://mhkdr.openei.org/files/343/Siddiqui_ACC_2021_UNPUBLISHED.pdf", "description": "Siddiqui et al. peer-reviewed (under review) conference paper submitted to American Control Conference (ACC) 2021. Details a receding horizon control strategy for real-time optimization of the tether length and elevation angle of an energy-harvesting kite.", "format": "pdf", "mediaType": "application/pdf", "title": "Siddiqui ACC - Optimal spooling control of kites in variable flow.pdf"}, {"@type": "dcat:Distribution", "accessURL": "https://mhkdr.openei.org/files/343/Reed_ACC_2021_UNPUBLISHED.pdf", "description": "Reed et al. peer-reviewed (under review) conference paper submitted to American Control Conference (ACC) 2020. Details a spooling profile optimization algorithm for ocean kites operating in a shear profile.", "format": "pdf", "mediaType": "application/pdf", "title": "Reed ACC - Spatial optimization of kite paths.pdf"}], "identifier": "https://data.openei.org/submissions/7986", "issued": "2020-03-02T07:00:00Z", "keyword": ["MHK", "Marine", "Hydrokinetic", "energy", "power", "kite", "control", "tidal kite", "spatial optimization", "CEC", "cyclic spooling", "airborne wind energy", "AWE", "Gaussian", "exploration", "exploitation", "tethered", "power take-off", "PTO", "model", "modeling", "cross-current", "controller", "tension", "figure-eight", "plant", "optimization", "spatial", "adaptive control", "receding horizon", "MATLAB", "cyclic control", "iterative learning", "path", "fly-gen", "ground-gen", "generator"], "landingPage": "https://mhkdr.openei.org/submissions/343", "license": "https://creativecommons.org/licenses/by/4.0/", "modified": "2021-03-01T20:11:47Z", "programCode": ["019:009"], "projectLead": "Carrie Noonan", "projectNumber": "EE0008635", "projectTitle": "Device Design and Robust Periodic Motion Control of an Ocean Kite System for Marine Hydrokinetic Energy Harvesting", "publisher": {"@type": "org:Organization", "name": "North Carolina State University"}, "spatial": "{\"type\":\"Polygon\",\"coordinates\":[[[-78.63222226921681,35.733223664115094],[-78.62460708061914,35.733223664115094],[-78.62460708061914,35.76299303766857],[-78.63222226921681,35.76299303766857],[-78.63222226921681,35.733223664115094]]]}", "title": "Control-based optimization for tethered tidal kite"}