The Experts below are selected from a list of 1653 Experts worldwide ranked by ideXlab platform
Craig Love - One of the best experts on this subject based on the ideXlab platform.
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Diagnosis of Tidal Turbine Vibration Data through Deep Neural Networks
European Conference of the Prognostics and Health Management Society, 2016Co-Authors: Grant S Galloway, THOMAS FAY, Victoria M. Catterson, Andrew Robb, Craig LoveAbstract:Tidal power is an emerging field of renewable energy, harnessing the power of regular and predictable tidal currents. However, maintenance of Submerged Equipment is a major challenge. Routine visual inspections of Equipment must be performed onshore, requiring the costly removal of turbines from the sea bed and resulting in long periods of downtime. The development of condition monitoring techniques providing automated fault detection can therefore be extremely beneficial to this industry, reducing the dependency on inspections and allowing maintenance to be planned efficiently. This paper investigates the use of deep learning approaches for fault detection within a tidal turbine's generator from vibration data. Training and testing data were recorded over two deployment periods of operation from an accelerometer sensor placed within the nacelle of the turbine, representing ideal and faulty responses over a range of operating conditions. The paper evaluates a deep learning approach through a stacked autoencoder network in comparison to feature-based classification methods, where features have been extracted over varying rotation speeds through the Vold-Kalman filter.
Grant S Galloway - One of the best experts on this subject based on the ideXlab platform.
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Diagnosis of Tidal Turbine Vibration Data through Deep Neural Networks
European Conference of the Prognostics and Health Management Society, 2016Co-Authors: Grant S Galloway, THOMAS FAY, Victoria M. Catterson, Andrew Robb, Craig LoveAbstract:Tidal power is an emerging field of renewable energy, harnessing the power of regular and predictable tidal currents. However, maintenance of Submerged Equipment is a major challenge. Routine visual inspections of Equipment must be performed onshore, requiring the costly removal of turbines from the sea bed and resulting in long periods of downtime. The development of condition monitoring techniques providing automated fault detection can therefore be extremely beneficial to this industry, reducing the dependency on inspections and allowing maintenance to be planned efficiently. This paper investigates the use of deep learning approaches for fault detection within a tidal turbine's generator from vibration data. Training and testing data were recorded over two deployment periods of operation from an accelerometer sensor placed within the nacelle of the turbine, representing ideal and faulty responses over a range of operating conditions. The paper evaluates a deep learning approach through a stacked autoencoder network in comparison to feature-based classification methods, where features have been extracted over varying rotation speeds through the Vold-Kalman filter.
THOMAS FAY - One of the best experts on this subject based on the ideXlab platform.
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Diagnosis of Tidal Turbine Vibration Data through Deep Neural Networks
European Conference of the Prognostics and Health Management Society, 2016Co-Authors: Grant S Galloway, THOMAS FAY, Victoria M. Catterson, Andrew Robb, Craig LoveAbstract:Tidal power is an emerging field of renewable energy, harnessing the power of regular and predictable tidal currents. However, maintenance of Submerged Equipment is a major challenge. Routine visual inspections of Equipment must be performed onshore, requiring the costly removal of turbines from the sea bed and resulting in long periods of downtime. The development of condition monitoring techniques providing automated fault detection can therefore be extremely beneficial to this industry, reducing the dependency on inspections and allowing maintenance to be planned efficiently. This paper investigates the use of deep learning approaches for fault detection within a tidal turbine's generator from vibration data. Training and testing data were recorded over two deployment periods of operation from an accelerometer sensor placed within the nacelle of the turbine, representing ideal and faulty responses over a range of operating conditions. The paper evaluates a deep learning approach through a stacked autoencoder network in comparison to feature-based classification methods, where features have been extracted over varying rotation speeds through the Vold-Kalman filter.
Victoria M. Catterson - One of the best experts on this subject based on the ideXlab platform.
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Diagnosis of Tidal Turbine Vibration Data through Deep Neural Networks
European Conference of the Prognostics and Health Management Society, 2016Co-Authors: Grant S Galloway, THOMAS FAY, Victoria M. Catterson, Andrew Robb, Craig LoveAbstract:Tidal power is an emerging field of renewable energy, harnessing the power of regular and predictable tidal currents. However, maintenance of Submerged Equipment is a major challenge. Routine visual inspections of Equipment must be performed onshore, requiring the costly removal of turbines from the sea bed and resulting in long periods of downtime. The development of condition monitoring techniques providing automated fault detection can therefore be extremely beneficial to this industry, reducing the dependency on inspections and allowing maintenance to be planned efficiently. This paper investigates the use of deep learning approaches for fault detection within a tidal turbine's generator from vibration data. Training and testing data were recorded over two deployment periods of operation from an accelerometer sensor placed within the nacelle of the turbine, representing ideal and faulty responses over a range of operating conditions. The paper evaluates a deep learning approach through a stacked autoencoder network in comparison to feature-based classification methods, where features have been extracted over varying rotation speeds through the Vold-Kalman filter.
Andrew Robb - One of the best experts on this subject based on the ideXlab platform.
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Diagnosis of Tidal Turbine Vibration Data through Deep Neural Networks
European Conference of the Prognostics and Health Management Society, 2016Co-Authors: Grant S Galloway, THOMAS FAY, Victoria M. Catterson, Andrew Robb, Craig LoveAbstract:Tidal power is an emerging field of renewable energy, harnessing the power of regular and predictable tidal currents. However, maintenance of Submerged Equipment is a major challenge. Routine visual inspections of Equipment must be performed onshore, requiring the costly removal of turbines from the sea bed and resulting in long periods of downtime. The development of condition monitoring techniques providing automated fault detection can therefore be extremely beneficial to this industry, reducing the dependency on inspections and allowing maintenance to be planned efficiently. This paper investigates the use of deep learning approaches for fault detection within a tidal turbine's generator from vibration data. Training and testing data were recorded over two deployment periods of operation from an accelerometer sensor placed within the nacelle of the turbine, representing ideal and faulty responses over a range of operating conditions. The paper evaluates a deep learning approach through a stacked autoencoder network in comparison to feature-based classification methods, where features have been extracted over varying rotation speeds through the Vold-Kalman filter.
