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Author: Herman Herman Publisher: ISBN: Category : Excavation Languages : en Pages : 143
Book Description
Abstract: "The goal of our research is to develop an autonomous robot for subsurface mapping. We are motivated by the growing need for mapping buried pipes, hazardous waste, landmines and other buried objects. Most of these are large scale mapping problems, and to manually construct subsurface maps in these cases would require a significant amount of resources. Therefore, automating the subsurface mapping process is an important factor in alleviating these problems. To achieve our goal, we have developed a robotic system that can autonomously gather and process Ground Penetrating Radar (GPR) data. The system uses a scanning laser rangefinder to construct an elevation map of an area. By using the elevation map, a robotic manipulator can follow the contour of the terrain when it moves the GPR antenna during the scanning process. The collected data are then processed to detect and locate buried objects. We have developed three new processing methods, two are volume based processing methods and one is a surface based processing method. In volume based processing, the 3-D data are directly processed to find the buried objects, while in surface based processing, the 3-D data are first reduced to a series of 2.5-D surfaces before further processing. Each of these methods has its own strengths and weaknesses. The volume based processing methods can be made very fast using parallel processing techniques, but they require an accurate propagation velocity of the GPR signal in the soil. On the other hand, the surface based processing method uses 3-D segmentation to recognize the shape of the buried objects, which does not require an accurate propagation velocity estimate. Both approaches are quite efficient and well suited for online data processing. In fact, they are so efficient that the current bottleneck in the subsurface mapping process is the data acquisition phase. The main contribution of the thesis is the development of an autonomous system for detecting and localizing buried objects. Specifically, we have developed three new methods to find buried objects in 3-D GPR data. Using these methods, we are able to autonomously obtain subsurface data, locate and recognize buried objects. These methods differ from existing GPR data processing methods because they can autonomously extract the location, orientation, and parameters of the buried objects from high resolution 3-D data. Most existing methods only enhance the GPR data for easier interpretation by human experts. There are some existing works in automated interpretation of GPR data, but they only work with 2-D GPR data. We implemented the three different methods and also tested them by building subsurface maps of various buried objects under different soil conditions. We also used these sub-surface mapping methods to demonstrate an autonomous buried object retrieval system. In summary, we have developed a robotic system which make [sic] subsurface mapping faster, more accurate and reliable."
Author: Herman Herman Publisher: ISBN: Category : Excavation Languages : en Pages : 143
Book Description
Abstract: "The goal of our research is to develop an autonomous robot for subsurface mapping. We are motivated by the growing need for mapping buried pipes, hazardous waste, landmines and other buried objects. Most of these are large scale mapping problems, and to manually construct subsurface maps in these cases would require a significant amount of resources. Therefore, automating the subsurface mapping process is an important factor in alleviating these problems. To achieve our goal, we have developed a robotic system that can autonomously gather and process Ground Penetrating Radar (GPR) data. The system uses a scanning laser rangefinder to construct an elevation map of an area. By using the elevation map, a robotic manipulator can follow the contour of the terrain when it moves the GPR antenna during the scanning process. The collected data are then processed to detect and locate buried objects. We have developed three new processing methods, two are volume based processing methods and one is a surface based processing method. In volume based processing, the 3-D data are directly processed to find the buried objects, while in surface based processing, the 3-D data are first reduced to a series of 2.5-D surfaces before further processing. Each of these methods has its own strengths and weaknesses. The volume based processing methods can be made very fast using parallel processing techniques, but they require an accurate propagation velocity of the GPR signal in the soil. On the other hand, the surface based processing method uses 3-D segmentation to recognize the shape of the buried objects, which does not require an accurate propagation velocity estimate. Both approaches are quite efficient and well suited for online data processing. In fact, they are so efficient that the current bottleneck in the subsurface mapping process is the data acquisition phase. The main contribution of the thesis is the development of an autonomous system for detecting and localizing buried objects. Specifically, we have developed three new methods to find buried objects in 3-D GPR data. Using these methods, we are able to autonomously obtain subsurface data, locate and recognize buried objects. These methods differ from existing GPR data processing methods because they can autonomously extract the location, orientation, and parameters of the buried objects from high resolution 3-D data. Most existing methods only enhance the GPR data for easier interpretation by human experts. There are some existing works in automated interpretation of GPR data, but they only work with 2-D GPR data. We implemented the three different methods and also tested them by building subsurface maps of various buried objects under different soil conditions. We also used these sub-surface mapping methods to demonstrate an autonomous buried object retrieval system. In summary, we have developed a robotic system which make [sic] subsurface mapping faster, more accurate and reliable."
Author: Lawrence B. Conyers Publisher: John Wiley & Sons ISBN: 1118949943 Category : Science Languages : en Pages : 157
Book Description
There has long been a strong collaboration between geologists and archaeologists, and the sub-field of geoarchaeology is well developed as a discipline in its own right. This book now bridges the gap between those fields and the geophysical technique of ground-penetrating radar (GPR), which allows for three-dimensional analysis of the ground to visualize both geological and archaeological materials. This method has the ability to produce images of the ground that display complex packages of materials, and allows researchers to integrate sedimentary units, soils and associated archaeological features in ways not possible using standard excavation techniques. The ability of GPR to visualize all these buried units can help archaeologists place ancient people within the landscapes and environments of their time, and understand their burial and preservation phenomena in three-dimensions. Readership: Advanced students in archaeology and geoarchaeology, as well as practicing archaeologists with an interest in GPS techniques.
Author: Dean Goodman Publisher: Springer Science & Business Media ISBN: 3642318576 Category : Science Languages : en Pages : 241
Book Description
GPR Remote Sensing in Archaeology provides a complete description of the processes needed to take raw GPR data all the way to the construction of subsurface images. The book provides an introduction to the “theory” of GPR by using a simulator that shows how radar profiles across simple model structures look and provides many examples so that the complexity of radar signatures can be understood. It continues with a review of the necessary radargram signal processes needed along with examples. The most comprehensive methodology to construct subsurface images from either coarsely spaced data using interpolation or from dense data from multi-channel equipment and 3D volume generation is presented, advanced imaging solutions such as overlay analysis are introduced, and numerous worldwide site case histories are shown. The authors present their studies in a way that most technical and non-technical users of the equipment will find essentials for implementing in their own subsurface investigations.
Author: Lawrence B. Conyers Publisher: Springer ISBN: 3319708902 Category : Science Languages : en Pages : 115
Book Description
This book presents the integrated use of magnetometry and ground-penetrating radar geophysical mapping to understand the human presence within buried archaeological landscapes. Ground-penetrating radar can be used to identify buried living surfaces, geological stratigraphy and the architectural remains of sites in three-dimensions. Magnetometry can produce images denoting differences on the composition of those materials, both anthropogenic and natural, but with more limited three-dimensional resolution. The integration of the two has a unique ability to resolve and interpret these buried materials, differentiated between the human-caused and natural layers, and place all buried features within historic landscapes. The final product of geophysical integration, along with some limited subsurface testing, produces a holistic analysis of human adaptations to, and modifications of, the ancient landscape. Examples are shown from sites in Roman Croatia and Britain, Medieval Ireland, Colonial Connecticut, and an Archaic site in the Colorado Rocky Mountains. These examples from very different environments, time periods and cultural groups illustrate how the integrated geophysical methodology can interpret, on a scale approaching many hectares, the ancient landscapes within which people lived.
Author: Carnegie-Mellon University. Robotics Institute Publisher: ISBN: Category : Ground penetrating radar Languages : en Pages : 11
Book Description
By combining the use of a position-cognizant, all-terrain mobile robot and a linear scanning mechanism, it is possible to acquire GPR records in a two-dimensional grid on the ground surface."
Author: Herman Herman
Author: Herman Herman
Author: Lawrence B. Conyers
Author: 
Author: Dean Goodman
Author: Lawrence B. Conyers
Author: Loris E. Asmussen
Author: Robert Beck
Author: Richard Thomas Houck
Author: Carnegie-Mellon University. Robotics Institute
Author: Nadiah Ismail