The Experts below are selected from a list of 114 Experts worldwide ranked by ideXlab platform
Dick Whittington Studio - One of the best experts on this subject based on the ideXlab platform.
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Aerial view facing northeast over Main Channel to Los Angeles Harbor
University of Southern California. Libraries, 1998Co-Authors: Dick Whittington StudioAbstract:Aerial view facing northeast over Main Channel to Los Angeles Harbor. East of the main channel are the Drydocks, Terminal Island, Dock Street, the United States Naval Shipyard at Long Beach, construction of the Vincent Thomas Toll Bridge (Highway 47), and the Cerritos Channel. At Center are Smith's Island and Mormon Island. San Pedro is in the foreground.; Streetscape. Oblique aerial photography
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Aerial view facing east over Main Channel to Los Angeles Harbor
University of Southern California. Libraries, 1998Co-Authors: Dick Whittington StudioAbstract:Aerial view facing east over Main Channel to Los Angeles Harbor. Harbor Boulevard and Front Street are in the foreground. East of the main channel are the Drydocks, Fish Harbor and the fish canneries, the Los Angeles Yacht Club, Terminal Island, Dock Street, the United States Naval Shipyard at Long Beach, construction of the Vincent Thomas Toll Bridge (Highway 47), and the Cerritos Channel.; Streetscape. Oblique aerial photography
Adam D Friedman - One of the best experts on this subject based on the ideXlab platform.
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lamb wave detection of limpet mines on ship hulls
Ultrasonics, 2009Co-Authors: Jill Bingham, Mark K Hinders, Adam D FriedmanAbstract:This paper describes the use of ultrasonic guided waves for identifying the mass loading due to underwater limpet mines on ship hulls. The Dynamic Wavelet Fingerprint Technique (DFWT) is used to render the guided wave mode information in two-dimensional binary images because the waveform features of interest are too subtle to identify in time domain. The use of wavelets allows both time and scale features from the original signals to be retained, and image processing can be used to automatically extract features that correspond to the arrival times of the guided wave modes. For further understanding of how the guided wave modes propagate through the real structures, a parallel processing, 3D elastic wave simulation is developed using the finite integration technique (EFIT). This full field, technique models situations that are too complex for analytical solutions, such as built up 3D structures. The simulations have produced informative visualizations of the guided wave modes in the structures as well as mimicking directly the output from sensors placed in the simulation space for direct comparison to experiments. Results from both drydock and in-water experiments with dummy mines are also shown.
Rose C.d. - One of the best experts on this subject based on the ideXlab platform.
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Automatic production planning for the construction of complex ships
2017Co-Authors: Rose C.d.Abstract:European shipyards specialize in building complex ship types including offshore vessels, yachts, dredgers, and cruise ships. One key difference between these ships and the simple cargo ships typically built in the Far East is the amount and variety of mission-related equipment required to operate the ships. Technical spaces of complex ships are numerous and densely packed. Outfitting is the shipbuilding process of installing this equipment and its supporting components (e.g. piping, ducting, and cabling). Most shipyards do not adequately plan the outfitting process. Instead, high level schedules are typically provided to outfitting subcontractors. These schedules indicate the time windows during which they must complete their installation tasks. Conflicts between the different stakeholders are addressed during weekly meetings. This outfitting planning approach is characterized by disorganization, poor communication, and a lack of transparency. As a result, the outfitting process of European shipyards is often plagued by delays, rework, and sub-optimization.A ship is constructed by first building large steel blocks, referred to as sections. Steel parts and profiles are welded together to create sections during the section building process. At the conclusion of section building, time is reserved for installing components in a section. The hull of the ship is formed by welding these sections together on a slipway or drydock. This process is referred to as erection. European shipyards mainly focus on planning the steel-related tasks of the section building and erection processes. However, their workload has shifted in recent years to become increasingly dominated by outfitting tasks. This mismatch further worsens the outfitting-related problems facing these shipyards.Automatic production planning can potentially mitigate some of the main problems facing European shipyards building complex ships. However, to maximize the effectiveness of such an approach, an integrated method must be created which considers all relevant portions of the shipbuilding process: erection, section building, and outfitting. This dissertation develops an Integrated Shipbuilding Planning Method. This method uses the characteristics of a shipyard, the geometry of a ship, and major project milestones to automatically generate an integrated erection, section building, and outfitting plan. The Integrated Shipbuilding Planning Method was not designed to replace existing shipyard planners, but instead enhance their decision-making abilities. The method aims to provide these planners with a set of high-quality production schedules that can be used as a starting point for drafting the initial plan.The foundation of Integrated Shipbuilding Planning Method is based on a mathematical model of the shipbuilding process. This model was synthesized from existing literature, expert opinion, and an analysis of the operations of a typical European shipyard. This model explicitly defines the geometric, operational, and temporal relationships that constrain the shipbuilding process. Novel techniques were developed to automatically extract several of these constraints from the data readily available in a shipyard. The mathematical model also defines the objectives used to measure the quality of a production schedule. A combination of multi-objective genetic algorithms and custom designed heuristics were used to solve the proposed mathematical model. This solution approach tailored historically successful optimization techniques to the specific problem structure of scheduling shipbuilding tasks. Although the developed solution approach does not guarantee that the optimal solution will be found, it allows for sufficiently high-quality solutions to be discovered in reasonable computational times.The Integrated Shipbuilding Planning Method was evaluated with a test case of a pipelaying ship recently delivered from a Dutch shipyard. This method created a variety of high-quality production plans of both the erection and section building processes in a reasonable computational time. The automatically generated production schedules significantly outperformed those manually generated by the shipyard planners. Especially large gains were seen with respect to the evenness of the outfitting workload and the time available to install components on the slipway. Furthermore, the negligible run time allows planners to quickly make adjustments and test different scenarios. The input data required for creating the section building and erection schedules matches the information that shipyard planners have access to at the start of a new project. Not only was the Integrated Shipbuilding Planning Method able to optimize the planning of the erection and section building independently, it was also shown to be capable of concurrently optimizing the planning of both processes.Implementing the Integrated Shipbuilding Planning Method in a shipyard for automatically scheduling the section building and erection processes should be relatively straightforward. This method works with the same data (both input and output) as the shipyard planners drafting the initial production schedules. A shipyard would still need to adapt the method to their own process by incorporating their own production data; modifying the constraints and objective to match their production process; tuning the parameters of the solution technique; and implementing the result in the work flow of their planners. However, the global approach and algorithms underlying the solution technique are directly applicable. A detailed outfitting schedule was also created for the test case ship using the Integrated Shipbuilding Planning Method. Although a high-quality solution was found, the required computational time was somewhat extensive due to the large problem size and complex nature of the relationships constraining the installation of outfitting components. The detailed outfitting schedule was used to determine the influence of the outfitting process on erection and section building. To generate the detailed outfitting schedule, a high level of geometric detail was required because such a schedule is defined on the component level. Such detailed geometry, however, is generally not fully available prior to the onset of outfitting due to the concurrent nature of the detailed engineering and production processes of modern European shipyards. The full implementation of the Integrated Shipbuilding Planning Method for automatically generating detailed outfitting schedules is currently limited by the extensive computational requirements and the timely availability of detailed geometric data.The Integrated Shipbuilding Planning Method was also used to examine two production scenarios to demonstrate its applicability in making strategic decisions. The method was first used to evaluate the performance of three different block building strategies in relation to the erection and section building processes. A recommendation was given for the best strategies assuming the shipyard prioritized having a level resource demand. The effect of the implementation of multi-skilled workers on the outfitting process was also examined. This scenario determined the effect of six different types of multi-skilled mounting teams on the total number of mounting teams required to build the test case ship. In both cases, the scenario analyses provided additional, useful information which could aid a shipyard in making strategic decisions. Because strategic decisions are generally based on historical data, the timely availability of detailed geometric data should not hinder the applicability of the Integrated Shipbuilding Planning Method for supporting such decisions.The Integrated Shipbuilding Planning Method is novel for several reasons. First, this method is the only automatic planning method developed for shipbuilding that fully incorporates the outfitting process. This method is also the first example of a scheduling methodology that concurrently plans the erection and section building tasks of a shipbuilding project. Furthermore, this approach demonstrates the feasibility of using a priority-based heuristic function in a multi-objective genetic algorithm to effectively schedule a large set of production tasks. Lastly, the production scenarios examined using the Integrated Shipbuilding Planning Method prove that it is possible for a shipyard to use optimization techniques to support strategic planning decisions
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Automatic production planning for the construction of complex ships
2017Co-Authors: Rose C.d.Abstract:European shipyards specialize in building complex ship types including offshore vessels, yachts, dredgers, and cruise ships. One key difference between these ships and the simple cargo ships typically built in the Far East is the amount and variety of mission-related equipment required to operate the ships. Technical spaces of complex ships are numerous and densely packed. Outfitting is the shipbuilding process of installing this equipment and its supporting components (e.g. piping, ducting, and cabling). Most shipyards do not adequately plan the outfitting process. Instead, high level schedules are typically provided to outfitting subcontractors. These schedules indicate the time windows during which they must complete their installation tasks. Conflicts between the different stakeholders are addressed during weekly meetings. This outfitting planning approach is characterized by disorganization, poor communication, and a lack of transparency. As a result, the outfitting process of European shipyards is often plagued by delays, rework, and sub-optimization.A ship is constructed by first building large steel blocks, referred to as sections. Steel parts and profiles are welded together to create sections during the section building process. At the conclusion of section building, time is reserved for installing components in a section. The hull of the ship is formed by welding these sections together on a slipway or drydock. This process is referred to as erection. European shipyards mainly focus on planning the steel-related tasks of the section building and erection processes. However, their workload has shifted in recent years to become increasingly dominated by outfitting tasks. This mismatch further worsens the outfitting-related problems facing these shipyards.Automatic production planning can potentially mitigate some of the main problems facing European shipyards building complex ships. However, to maximize the effectiveness of such an approach, an integrated method must be created which considers all relevant portions of the shipbuilding process: erection, section building, and outfitting. This dissertation develops an Integrated Shipbuilding Planning Method. This method uses the characteristics of a shipyard, the geometry of a ship, and major project milestones to automatically generate an integrated erection, section building, and outfitting plan. The Integrated Shipbuilding Planning Method was not designed to replace existing shipyard planners, but instead enhance their decision-making abilities. The method aims to provide these planners with a set of high-quality production schedules that can be used as a starting point for drafting the initial plan.The foundation of Integrated Shipbuilding Planning Method is based on a mathematical model of the shipbuilding process. This model was synthesized from existing literature, expert opinion, and an analysis of the operations of a typical European shipyard. This model explicitly defines the geometric, operational, and temporal relationships that constrain the shipbuilding process. Novel techniques were developed to automatically extract several of these constraints from the data readily available in a shipyard. The mathematical model also defines the objectives used to measure the quality of a production schedule. A combination of multi-objective genetic algorithms and custom designed heuristics were used to solve the proposed mathematical model. This solution approach tailored historically successful optimization techniques to the specific problem structure of scheduling shipbuilding tasks. Although the developed solution approach does not guarantee that the optimal solution will be found, it allows for sufficiently high-quality solutions to be discovered in reasonable computational times.The Integrated Shipbuilding Planning Method was evaluated with a test case of a pipelaying ship recently delivered from a Dutch shipyard. This method created a variety of high-quality production plans of both the erection and section building processes in a reasonable computational time. The automatically generated production schedules significantly outperformed those manually generated by the shipyard planners. Especially large gains were seen with respect to the evenness of the outfitting workload and the time available to install components on the slipway. Furthermore, the negligible run time allows planners to quickly make adjustments and test different scenarios. The input data required for creating the section building and erection schedules matches the information that shipyard planners have access to at the start of a new project. Not only was the Integrated Shipbuilding Planning Method able to optimize the planning of the erection and section building independently, it was also shown to be capable of concurrently optimizing the planning of both processes.Implementing the Integrated Shipbuilding Planning Method in a shipyard for automatically scheduling the section building and erection processes should be relatively straightforward. This method works with the same data (both input and output) as the shipyard planners drafting the initial production schedules. A shipyard would still need to adapt the method to their own process by incorporating their own production data; modifying the constraints and objective to match their production process; tuning the parameters of the solution technique; and implementing the result in the work flow of their planners. However, the global approach and algorithms underlying the solution technique are directly applicable. A detailed outfitting schedule was also created for the test case ship using the Integrated Shipbuilding Planning Method. Although a high-quality solution was found, the required computational time was somewhat extensive due to the large problem size and complex nature of the relationships constraining the installation of outfitting components. The detailed outfitting schedule was used to determine the influence of the outfitting process on erection and section building. To generate the detailed outfitting schedule, a high level of geometric detail was required because such a schedule is defined on the component level. Such detailed geometry, however, is generally not fully available prior to the onset of outfitting due to the concurrent nature of the detailed engineering and production processes of modern European shipyards. The full implementation of the Integrated Shipbuilding Planning Method for automatically generating detailed outfitting schedules is currently limited by the extensive computational requirements and the timely availability of detailed geometric data.The Integrated Shipbuilding Planning Method was also used to examine two production scenarios to demonstrate its applicability in making strategic decisions. The method was first used to evaluate the performance of three different block building strategies in relation to the erection and section building processes. A recommendation was given for the best strategies assuming the shipyard prioritized having a level resource demand. The effect of the implementation of multi-skilled workers on the outfitting process was also examined. This scenario determined the effect of six different types of multi-skilled mounting teams on the total number of mounting teams required to build the test case ship. In both cases, the scenario analyses provided additional, useful information which could aid a shipyard in making strategic decisions. Because strategic decisions are generally based on historical data, the timely availability of detailed geometric data should not hinder the applicability of the Integrated Shipbuilding Planning Method for supporting such decisions.The Integrated Shipbuilding Planning Method is novel for several reasons. First, this method is the only automatic planning method developed for shipbuilding that fully incorporates the outfitting process. This method is also the first example of a scheduling methodology that concurrently plans the erection and section building tasks of a shipbuilding project. Furthermore, this approach demonstrates the feasibility of using a priority-based heuristic function in a multi-objective genetic algorithm to effectively schedule a large set of production tasks. Lastly, the production scenarios examined using the Integrated Shipbuilding Planning Method prove that it is possible for a shipyard to use optimization techniques to support strategic planning decisions.Ship Design, Production and Operation
Jill Bingham - One of the best experts on this subject based on the ideXlab platform.
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lamb wave detection of limpet mines on ship hulls
Ultrasonics, 2009Co-Authors: Jill Bingham, Mark K Hinders, Adam D FriedmanAbstract:This paper describes the use of ultrasonic guided waves for identifying the mass loading due to underwater limpet mines on ship hulls. The Dynamic Wavelet Fingerprint Technique (DFWT) is used to render the guided wave mode information in two-dimensional binary images because the waveform features of interest are too subtle to identify in time domain. The use of wavelets allows both time and scale features from the original signals to be retained, and image processing can be used to automatically extract features that correspond to the arrival times of the guided wave modes. For further understanding of how the guided wave modes propagate through the real structures, a parallel processing, 3D elastic wave simulation is developed using the finite integration technique (EFIT). This full field, technique models situations that are too complex for analytical solutions, such as built up 3D structures. The simulations have produced informative visualizations of the guided wave modes in the structures as well as mimicking directly the output from sensors placed in the simulation space for direct comparison to experiments. Results from both drydock and in-water experiments with dummy mines are also shown.
Mark K Hinders - One of the best experts on this subject based on the ideXlab platform.
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lamb wave detection of limpet mines on ship hulls
Ultrasonics, 2009Co-Authors: Jill Bingham, Mark K Hinders, Adam D FriedmanAbstract:This paper describes the use of ultrasonic guided waves for identifying the mass loading due to underwater limpet mines on ship hulls. The Dynamic Wavelet Fingerprint Technique (DFWT) is used to render the guided wave mode information in two-dimensional binary images because the waveform features of interest are too subtle to identify in time domain. The use of wavelets allows both time and scale features from the original signals to be retained, and image processing can be used to automatically extract features that correspond to the arrival times of the guided wave modes. For further understanding of how the guided wave modes propagate through the real structures, a parallel processing, 3D elastic wave simulation is developed using the finite integration technique (EFIT). This full field, technique models situations that are too complex for analytical solutions, such as built up 3D structures. The simulations have produced informative visualizations of the guided wave modes in the structures as well as mimicking directly the output from sensors placed in the simulation space for direct comparison to experiments. Results from both drydock and in-water experiments with dummy mines are also shown.
