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Automatic Modeling and Localization for Object Recognition

Being able to accurately estimate an object's pose (location) in an image is important for practical implementations and applications of object recognition. Recognition algorithms often trade off accuracy of the pose estimate for efficiency -- usually resulting in brittle and inaccurate recogni...

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Main Author:	Wheeler, Mark D
Format:	Report
Language:	English
Subjects:	ALGORITHMS AUTOMATIC AUTOMATIC OBJECT MODELING CONSENSUS Cybernetics LOCALIZATION M-ESTIMATION OBJECT RECOGNITION POSE REFINEMENT POSITION(LOCATION) RECOGNITION ROBUST STATISTICS STATISTICAL PROCESSES Statistics and Probability SURFACE MERGING THESES THREE DIMENSIONAL TRACKING
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creator	Wheeler, Mark D
description	Being able to accurately estimate an object's pose (location) in an image is important for practical implementations and applications of object recognition. Recognition algorithms often trade off accuracy of the pose estimate for efficiency -- usually resulting in brittle and inaccurate recognition. One solution is object localization -- a local search for the object's true pose given a rough initial estimate of the pose. Localization is made difficult by the unfavorable characteristics (for example, noise, clutter, occlusion and missing data) of real images. In this thesis, we present novel algorithms for localizing 3D objects in 3D range-image data (3D-3D localization) and for localizing 3D objects in 2D intensity-image data (3D-2D localization). Our localization algorithms utilize robust statistical techniques to reduce the sensitivity of the algorithms to the noise, clutter, missing data, and occlusion which are common in real images. Our localization results demonstrate that our algorithms can accurately determine the pose in noisy, cluttered images despite significant errors in the initial pose estimate. Acquiring accurate object models that facilitate localization is also of great practical importance for object recognition. In the past, models for recognition and localization were typically created by hand using computer-aided design (CAD) tools. Manual modeling suffers from expense and accuracy limitations. In this thesis, we present novel algorithms to automatically construct object-localization models from many images of the object. We present a consensus-search approach to determine which parts of the image justifiably constitute inclusion in the model. Using this approach, our modeling algorithms are relatively insensitive to the imperfections and noise typical of real image data. Our results demonstrate that our modeling algorithms can construct very accurate geometric models from rather noisy input data. Sponsored in part by Advanced Research Projects Agency (ARPA), and by the Office of Naval Research (ONR) contract no's. N00014-95-1-0591 and N00014-93-1-1220. The original document contains color images.
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Recognition algorithms often trade off accuracy of the pose estimate for efficiency -- usually resulting in brittle and inaccurate recognition. One solution is object localization -- a local search for the object's true pose given a rough initial estimate of the pose. Localization is made difficult by the unfavorable characteristics (for example, noise, clutter, occlusion and missing data) of real images. In this thesis, we present novel algorithms for localizing 3D objects in 3D range-image data (3D-3D localization) and for localizing 3D objects in 2D intensity-image data (3D-2D localization). Our localization algorithms utilize robust statistical techniques to reduce the sensitivity of the algorithms to the noise, clutter, missing data, and occlusion which are common in real images. Our localization results demonstrate that our algorithms can accurately determine the pose in noisy, cluttered images despite significant errors in the initial pose estimate. Acquiring accurate object models that facilitate localization is also of great practical importance for object recognition. In the past, models for recognition and localization were typically created by hand using computer-aided design (CAD) tools. Manual modeling suffers from expense and accuracy limitations. In this thesis, we present novel algorithms to automatically construct object-localization models from many images of the object. We present a consensus-search approach to determine which parts of the image justifiably constitute inclusion in the model. Using this approach, our modeling algorithms are relatively insensitive to the imperfections and noise typical of real image data. Our results demonstrate that our modeling algorithms can construct very accurate geometric models from rather noisy input data. Sponsored in part by Advanced Research Projects Agency (ARPA), and by the Office of Naval Research (ONR) contract no's. N00014-95-1-0591 and N00014-93-1-1220. 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Acquiring accurate object models that facilitate localization is also of great practical importance for object recognition. In the past, models for recognition and localization were typically created by hand using computer-aided design (CAD) tools. Manual modeling suffers from expense and accuracy limitations. In this thesis, we present novel algorithms to automatically construct object-localization models from many images of the object. We present a consensus-search approach to determine which parts of the image justifiably constitute inclusion in the model. Using this approach, our modeling algorithms are relatively insensitive to the imperfections and noise typical of real image data. Our results demonstrate that our modeling algorithms can construct very accurate geometric models from rather noisy input data. Sponsored in part by Advanced Research Projects Agency (ARPA), and by the Office of Naval Research (ONR) contract no's. N00014-95-1-0591 and N00014-93-1-1220. 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Acquiring accurate object models that facilitate localization is also of great practical importance for object recognition. In the past, models for recognition and localization were typically created by hand using computer-aided design (CAD) tools. Manual modeling suffers from expense and accuracy limitations. In this thesis, we present novel algorithms to automatically construct object-localization models from many images of the object. We present a consensus-search approach to determine which parts of the image justifiably constitute inclusion in the model. Using this approach, our modeling algorithms are relatively insensitive to the imperfections and noise typical of real image data. Our results demonstrate that our modeling algorithms can construct very accurate geometric models from rather noisy input data. Sponsored in part by Advanced Research Projects Agency (ARPA), and by the Office of Naval Research (ONR) contract no's. N00014-95-1-0591 and N00014-93-1-1220. 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source	DTIC Technical Reports
subjects	ALGORITHMS AUTOMATIC AUTOMATIC OBJECT MODELING CONSENSUS Cybernetics LOCALIZATION M-ESTIMATION OBJECT RECOGNITION POSE REFINEMENT POSITION(LOCATION) RECOGNITION ROBUST STATISTICS STATISTICAL PROCESSES Statistics and Probability SURFACE MERGING THESES THREE DIMENSIONAL TRACKING
title	Automatic Modeling and Localization for Object Recognition
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