Your search keyword '"Tannenbaum, Allen"' showing total 17 results

1. Simultaneous Multi-object Segmentation Using Local Robust Statistics and Contour Interaction

Author

Gao, Yi, Tannenbaum, Allen, Kikinis, Ron, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Sudan, Madhu, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Vardi, Moshe Y., Series editor, Weikum, Gerhard, Series editor, Menze, Bjoern, editor, Langs, Georg, editor, Tu, Zhuowen, editor, and Criminisi, Antonio, editor

Published

2011

2. Affine invariant gradient flows

Author

Olver, Peter J., Sapiro, Guillermo, Tannenbaum, Allen, Thoma, M., editor, Berger, Marie-Odile, editor, Deriche, Rachid, editor, Herlin, Isabelle, editor, Jaffré, Jérome, editor, and Morel, Jean-Michel, editor

Published

1996

3. Guiding Image Segmentation on the Fly: Interactive Segmentation From a Feedback Control Perspective.

Author

Zhu, Liangjia, Karasev, Peter, Kolesov, Ivan, Sandhu, Romeil, and Tannenbaum, Allen

Subjects

IMAGE segmentation, DYNAMICAL systems, IMAGING systems, COMPUTER vision, FEEDBACK control systems

Abstract

Image segmentation is a fundamental problem in computational vision and medical imaging. Designing a generic automated method that works for various objects and imaging modalities is a formidable task. Instead of proposing a new specific segmentation algorithm, we present a general design principle on how to integrate user interactions from the perspective of feedback control theory. Lyapunov stability analysis is employed to design and analyze an interactive segmentation system. Then, stabilization conditions are derived to guide the algorithm design. Finally, the effectiveness and robustness of the proposed method are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2018

4. A Kalman Filtering Perspective for Multiatlas Segmentation.

Author

Yi Gao, Liangjia Zhu, Cates, Joshua, MacLeod, Rob S., Bouix, Sylvain, and Tannenbaum, Allen

Subjects

IMAGE segmentation, IMAGE registration, KALMAN filtering, DIGITAL image processing, DYNAMICAL systems, IMAGE analysis

Abstract

In multiatlas segmentation, one typically registers several atlases to the novel image, and their respective segmented label images are transformed and fused to form the final segmentation. In this work, we provide a new dynamical system perspective for multiatlas segmentation, inspired by the following fact: The transformation that aligns the current atlas to the novel image can be not only computed by direct registration but also inferred from the transformation that aligns the previous atlas to the image together with the transformation between the two atlases. This process is similar to the global positioning system on a vehicle, which gets position by inquiring from the satellite and by employing the previous location and velocity--neither answer in isolation being perfect. To solve this problem, a dynamical system scheme is crucial to combine the two pieces of information; for example, a Kalman filtering scheme is used. Accordingly, in this work, a Kalman multiatlas segmentation is proposed to stabilize the global/affine registration step. The contributions of this work are twofold. First, it provides a new dynamical systematic perspective for standard independent multiatlas registrations, and it is solved by Kalman filtering. Second, with very little extra computation, it can be combined with most existing multiatlas segmentation schemes for better registration/segmentation accuracy. [ABSTRACT FROM AUTHOR]

Published

2015

5. Depth invariant visual servoing.

Author

Karasev, Peter A., Serrano, Miguel Moises, Vela, Patricio A., and Tannenbaum, Allen

Abstract

This paper studies the problem of achieving consistent performance for visual servoing. Given the nonlinearities introduced by the camera projection equations in monocular visual servoing systems, many control algorithms experience non-uniform performance bounds. The variable performance bounds arise from depth dependence in the error rates. In order to guarantee depth invariant performance bounds, the depth nonlinearity must be cancelled, however estimating distance along the optical axis is problematic when faced with an object with unknown geometry. By tracking a planar visual feature on a given target, and measuring the area of the planar feature, a distance invariant input to state stable visual servoing controller is derived. Two approaches are given for achieving the visual tracking. Both of these approaches avoid the need to maintain long-term tracks of individual feature points. Realistic image uncertainty is captured in experimental tests that control the camera motion in a 3D renderer using the observed image data for feedback. [ABSTRACT FROM PUBLISHER]

Published

2011

6. Automatic Segmentation of the Left Atrium From MR Images via Variational Region Growing With a Moments-Based Shape Prior.

Author

Zhu, Liangjia, Gao, Yi, Yezzi, Anthony, and Tannenbaum, Allen

Subjects

IMAGE segmentation, AUTOMATION, LEFT heart atrium, ABLATION techniques, ROBUST control, MAGNETIC resonance imaging, ATRIAL fibrillation

Abstract

The planning and evaluation of left atrial ablation procedures are commonly based on the segmentation of the left atrium, which is a challenging task due to large anatomical variations. In this paper, we propose an automatic approach for segmenting the left atrium from magnetic resonance imagery. The segmentation problem is formulated as a problem in variational region growing. In particular, the method starts locally by searching for a seed region of the left atrium from an MR slice. A global constraint is imposed by applying a shape prior to the left atrium represented by Zernike moments. The overall growing process is guided by the robust statistics of intensities from the seed region along with the shape prior to capture the entire atrial region. The robustness and accuracy of our approach are demonstrated by experimental results from 64 human MR images. [ABSTRACT FROM AUTHOR]

Published

2013

7. Interactive Medical Image Segmentation Using PDE Control of Active Contours.

Author

Karasev, Peter, Kolesov, Ivan, Fritscher, Karl, Vela, Patricio, Mitchell, Phillip, and Tannenbaum, Allen

Subjects

INTERACTIVE computer systems, MEDICAL imaging systems, IMAGE segmentation, IMAGE reconstruction, PARTIAL differential equations, COMPUTED tomography

Abstract

Segmentation of injured or unusual anatomic structures in medical imagery is a problem that has continued to elude fully automated solutions. In this paper, the goal of easy-to-use and consistent interactive segmentation is transformed into a control synthesis problem. A nominal level set partial differential equation (PDE) is assumed to be given; this open-loop system achieves correct segmentation under ideal conditions, but does not agree with a human expert's ideal boundary for real image data. Perturbing the state and dynamics of a level set PDE via the accumulated user input and an observer-like system leads to desirable closed-loop behavior. The input structure is designed such that a user can stabilize the boundary in some desired state without needing to understand any mathematical parameters. Effectiveness of the technique is illustrated with applications to the challenging segmentations of a patellar tendon in magnetic resonance and a shattered femur in computed tomography. [ABSTRACT FROM AUTHOR]

Published

2013

8. Sparse Texture Active Contour.

Author

Gao, Yi, Bouix, Sylvain, Shenton, Martha, and Tannenbaum, Allen

Subjects

IMAGE segmentation, NONPARAMETRIC estimation, CONTOURS (Cartography), FRACTAL dimensions, MARKOV random fields, GABOR filters, IMAGE reconstruction, SIGNAL denoising

Abstract

In image segmentation, we are often interested in using certain quantities to characterize the object, and perform the classification based on criteria such as mean intensity, gradient magnitude, and responses to certain predefined filters. Unfortunately, in many cases such quantities are not adequate to model complex textured objects. Along a different line of research, the sparse characteristic of natural signals has been recognized and studied in recent years. Therefore, how such sparsity can be utilized, in a non-parametric way, to model the object texture and assist the textural image segmentation process is studied in this paper, and a segmentation scheme based on the sparse representation of the texture information is proposed. More explicitly, the texture is encoded by the dictionaries constructed from the user initialization. Then, an active contour is evolved to optimize the fidelity of the representation provided by the dictionary of the target. In doing so, not only a non-parametric texture modeling technique is provided, but also the sparsity of the representation guarantees the computation efficiency. The experiments are carried out on the publicly available image data sets which contain a large variety of texture images, to analyze the user interaction, performance statistics, and to highlight the algorithm's capability of robustly extracting textured regions from an image. [ABSTRACT FROM AUTHOR]

Published

2013

9. Self-Crossing Detection and Location for Parametric Active Contours.

Author

Nakhmani, Arie and Tannenbaum, Allen

Subjects

*IMAGE converters, *VIDEOS, *ALGORITHMS, *IMAGE segmentation, *DIGITAL image processing, *MATHEMATICAL models, *TOPOLOGY

Abstract

Active contours are very popular tools for video tracking and image segmentation. Parameterized contours are used due to their fast evolution and have become the method of choice in the Sobolev context. Unfortunately, these contours are not easily adaptable to topological changes, and they may sometimes develop undesirable loops, resulting in erroneous results. To solve such topological problems, one needs an algorithm for contour self-crossing detection. We propose a simple methodology via simple techniques from differential topology. The detection is accomplished by inspecting the total net change of a given contour's angle, without point sorting and plane sweeping. We discuss the efficient implementation of the algorithm. We also provide algorithms for locating crossings by angle considerations and by plotting the four-connected lines between the discrete contour points. The proposed algorithms can be added to any parametric active-contour model. We show examples of successful tracking in real-world video sequences by Sobolev active contours and the proposed algorithms and provide ideas for further research. [ABSTRACT FROM PUBLISHER]

Published

2012

10. Object Tracking and Target Reacquisition Based on 3-D Range Data for Moving Vehicles.

Author

Lee, Jehoon, Lankton, Shawn, and Tannenbaum, Allen

Subjects

THREE-dimensional display systems, CINEMATOGRAPHY, INFORMATION filtering, IMAGE processing, PRINCIPAL components analysis, ALGORITHMS, ROBUST control, AUTOMATIC tracking

Abstract

In this paper, we propose an approach for tracking an object of interest based on 3-D range data. We employ particle filtering and active contours to simultaneously estimate the global motion of the object and its local deformations. The proposed algorithm takes advantage of range information to deal with the challenging (but common) situation in which the tracked object disappears from the image domain entirely and reappears later. To cope with this problem, a method based on principle component analysis (PCA) of shape information is proposed. In the proposed method, if the target disappears out of frame, shape similarity energy is used to detect target candidates that match a template shape learned online from previously observed frames. Thus, we require no a priori knowledge of the target's shape. Experimental results show the practical applicability and robustness of the proposed algorithm in realistic tracking scenarios. [ABSTRACT FROM AUTHOR]

Published

2011

11. Tubular Surface Segmentation for Extracting Anatomical Structures From Medical Imagery.

Author

Mohan, Vandana, Sundaramoorthi, Ganesh, and Tannenbaum, Allen

Subjects

IMAGE processing, ANGIOGRAPHY, DIAGNOSTIC imaging, ALGORITHMS, TOMOGRAPHY, BLOOD vessels

Abstract

This work provides a model for tubular structures, and devises an algorithm to automatically extract tubular anatomical structures from medical imagery. Our model fits many anatomical structures in medical imagery, in particular, various fiber bundles in the brain (imaged through diffusion-weighted magnetic resonance (DW-MRI)) such as the cingulum bundle, and blood vessel trees in computed tomography angiograms (CTAs). Extraction of the cingulum bundle is of interest because of possible ties to schizophrenia, and extracting blood vessels is helpful in the diagnosis of cardiovascular diseases. The tubular model we propose has advantages over many existing approaches in literature: fewer degrees-of-freedom over a general deformable surface hence energies defined on such tubes are less sensitive to undesirable local minima, and the tube (in 3-D) can be naturally represented by a 4-D curve (a radius function and centerline), which leads to computationally less costly algorithms and has the advantage that the centerline of the tube is obtained without additional effort. Our model also generalizes to tubular trees, and the extraction algorithm that we design automatically detects and evolves branches of the tree. We demonstrate the performance of our algorithm on 20 datasets of DW-MRI data and 32 datasets of CTA, and quantify the results of our algorithm when expert segmentations are available. [ABSTRACT FROM PUBLISHER]

Published

2010

12. A Coupled Global Registration and Segmentation Framework With Application to Magnetic Resonance Prostate Imagery.

Author

Gao, Yi, Sandhu, Romeil, Fichtinger, Gabor, and Tannenbaum, Allen Robert

Abstract

Extracting the prostate from magnetic resonance (MR) imagery is a challenging and important task for medical image analysis and surgical planning. We present in this work a unified shape-based framework to extract the prostate from MR prostate imagery. In many cases, shape-based segmentation is a two-part problem. First, one must properly align a set of training shapes such that any variation in shape is not due to pose. Then segmentation can be performed under the constraint of the learnt shape. However, the general registration task of prostate shapes becomes increasingly difficult due to the large variations in pose and shape in the training sets, and is not readily handled through existing techniques. Thus, the contributions of this paper are twofold. We first explicitly address the registration problem by representing the shapes of a training set as point clouds. In doing so, we are able to exploit the more global aspects of registration via a certain particle filtering based scheme. In addition, once the shapes have been registered, a cost functional is designed to incorporate both the local image statistics as well as the learnt shape prior. We provide experimental results, which include several challenging clinical data sets, to highlight the algorithm's capability of robustly handling supine/prone prostate registration and the overall segmentation task. [ABSTRACT FROM PUBLISHER]

Published

2010

13. Localizing Region-Based Active Contours.

Author

Lankton, Shawn and Tannenbaum, Allen

Subjects

*MATHEMATICAL reformulation, *LOCALIZATION theory, *MODELS & modelmaking, *HETEROGENEITY, *FORCE & energy, *IMAGE processing

Abstract

In this paper, we propose a natural framework that allows any region-based segmentation energy to be re-formulated in a local way. We consider local rather than global image statistics and evolve a contour based on local information. Localized contours are capable of segmenting objects with heterogeneous feature profiles that would be difficult to capture correctly using a standard global method. The presented technique is versatile enough to be used with any global region-based active contour energy and instill in it the benefits of localization. We describe this framework and demonstrate the localization of three well-known energies in order to illustrate how our framework can be applied to any energy. We then compare each localized energy to its global counterpart to show the improvements that can be achieved. Next, an in-depth study of the behaviors of these energies in response to the degree of localization is given. Finally, we show results on challenging images to illustrate the robust and accurate segmentations that are possible with this new class of active contour models. [ABSTRACT FROM AUTHOR]

Published

2008

14. Image Segmentation Using Active Contours Driven by the Bhattacharyya Gradient Flow.

Author

Michailovich, Oleg, Rathi, Yogesh, and Tannenbaum, Allen

Subjects

IMAGE processing, IMAGING systems, IMAGE analysis, PIXELS, DIGITAL images, INFORMATION processing

Abstract

This paper addresses the problem of image segmentation by means of active contours, whose evolution is driven by the gradient flow derived from an energy functional that is based on the Bhattacharyya distance. In particular, given the values of a photo- metric variable (or of a set thereof), which is to be used for classifying the image pixels, the active contours are designed to converge to the shape that results in maximal discrepancy between the empirical distributions of the photometric variable inside and outside of the contours. The above discrepancy is measured by means of the Bhattacharyya distance that proves to be an extremely useful tool for solving the problem at hand. The proposed methodology can be viewed as a generalization of the segmentation methods, in which active contours maximize the difference between a finite number of empirical moments of the ‘inside’ and ‘outside’ distributions. Furthermore, it is shown that the proposed methodology is very versatile and flexible in the sense that it allows one to easily accommodate a diversity of the image features based on which the segmentation should be performed. As an additional contribution, a method for automatically adjusting the smoothness properties of the empirical distributions is proposed. Such a procedure is crucial in situations when the number of data samples (supporting a certain segmentation class) varies considerably in the course of the evolution of the active contour. In this case, the smoothness properties of the empirical distributions have to be properly adjusted to avoid either over-or underestimation artifacts. Finally, a number of relevant segmentation results are demonstrated and some further research directions are discussed. [ABSTRACT FROM AUTHOR]

Published

2007

15. A Nonrigid Kernel-Based Framework for 2D-3D Pose Estimation and 2D Image Segmentation.

Author

Sandhu, Romeil, Dambreville, Samuel, Yezzi, Anthony, and Tannenbaum, Allen

Subjects

KERNEL functions, IMAGE processing, NONLINEAR theories, MANIFOLDS (Mathematics), MATHEMATICAL optimization, DIMENSIONAL analysis, PRINCIPAL components analysis

Abstract

In this work, we present a nonrigid approach to jointly solving the tasks of 2D-3D pose estimation and 2D image segmentation. In general, most frameworks that couple both pose estimation and segmentation assume that one has exact knowledge of the 3D object. However, under nonideal conditions, this assumption may be violated if only a general class to which a given shape belongs is given (e.g., cars, boats, or planes). Thus, we propose to solve the 2D-3D pose estimation and 2D image segmentation via nonlinear manifold learning of 3D embedded shapes for a general class of objects or deformations for which one may not be able to associate a skeleton model. Thus, the novelty of our method is threefold: First, we present and derive a gradient flow for the task of nonrigid pose estimation and segmentation. Second, due to the possible nonlinear structures of one's training set, we evolve the preimage obtained through kernel PCA for the task of shape analysis. Third, we show that the derivation for shape weights is general. This allows us to use various kernels, as well as other statistical learning methodologies, with only minimal changes needing to be made to the overall shape evolution scheme. In contrast with other techniques, we approach the nonrigid problem, which is an infinite-dimensional task, with a finite-dimensional optimization scheme. More importantly, we do not explicitly need to know the interaction between various shapes such as that needed for skeleton models as this is done implicitly through shape learning. We provide experimental results on several challenging pose estimation and segmentation scenarios. [ABSTRACT FROM PUBLISHER]

Published

2011

16. A 3D interactive multi-object segmentation tool using local robust statistics driven active contours

Author

Gao, Yi, Kikinis, Ron, Bouix, Sylvain, Shenton, Martha, and Tannenbaum, Allen

Subjects

*IMAGE segmentation, *ROBUST statistics, *DIAGNOSTIC imaging, *ALGORITHMS, *TOMOGRAPHY, *MAGNETIC resonance imaging

Abstract

Abstract: Extracting anatomical and functional significant structures renders one of the important tasks for both the theoretical study of the medical image analysis, and the clinical and practical community. In the past, much work has been dedicated only to the algorithmic development. Nevertheless, for clinical end users, a well designed algorithm with an interactive software is necessary for an algorithm to be utilized in their daily work. Furthermore, the software would better be open sourced in order to be used and validated by not only the authors but also the entire community. Therefore, the contribution of the present work is twofolds: first, we propose a new robust statistics based conformal metric and the conformal area driven multiple active contour framework, to simultaneously extract multiple targets from MR and CT medical imagery in 3D. Second, an open source graphically interactive 3D segmentation tool based on the aforementioned contour evolution is implemented and is publicly available for end users on multiple platforms. In using this software for the segmentation task, the process is initiated by the user drawn strokes (seeds) in the target region in the image. Then, the local robust statistics are used to describe the object features, and such features are learned adaptively from the seeds under a non-parametric estimation scheme. Subsequently, several active contours evolve simultaneously with their interactions being motivated by the principles of action and reaction—this not only guarantees mutual exclusiveness among the contours, but also no longer relies upon the assumption that the multiple objects fill the entire image domain, which was tacitly or explicitly assumed in many previous works. In doing so, the contours interact and converge to equilibrium at the desired positions of the desired multiple objects. Furthermore, with the aim of not only validating the algorithm and the software, but also demonstrating how the tool is to be used, we provide the reader reproducible experiments that demonstrate the capability of the proposed segmentation tool on several public available data sets. [Copyright &y& Elsevier]

Published

2012

17. Multiscale 3D shape representation and segmentation with applications to hippocampal/caudate extraction from brain MRI

Author

Gao, Yi, Corn, Benjamin, Schifter, Dan, and Tannenbaum, Allen

Subjects

*HIPPOCAMPUS (Brain), *MAGNETIC resonance imaging of the brain, *IMAGE segmentation, *MEDICAL imaging systems, *THREE-dimensional imaging, *IMAGE quality in imaging systems, *IMAGE analysis

Abstract

Abstract: Extracting structure of interest from medical images is an important yet tedious work. Due to the image quality, the shape knowledge is widely used for assisting and constraining the segmentation process. In many previous works, shape knowledge was incorporated by first constructing a shape space from training cases, and then constraining the segmentation process to be within the learned shape space. However, such an approach has certain limitations due to the number of variations, eigen-shapemodes, that can be captured in the learned shape space. Moreover, small scale shape variances are usually overwhelmed by those in the large scale, and therefore the local shape information is lost. In this work, we present a multiscale representation for shapes with arbitrary topology, and a fully automatic method to segment the target organ/tissue from medical images using such multiscale shape information and local image features. First, we handle the problem of lacking eigen-shapemodes by providing a multiscale shape representation using the wavelet transform. Consequently, the shape variances existing in the training shapes captured by the statistical learning step are also represented at various scales. Note that by doing so, one can greatly enrich the eigen-shapemodes as well as capture small scale shape changes. Furthermore, in order to make full use of the training information, not only the shape but also the grayscale training images are utilized in a multi-atlas initialization procedure. By combining such initialization with the multiscale shape knowledge, we perform segmentation tests for challenging medical data sets where the target objects have low contrast and sharp corner structures, and demonstrate the statistically significant improvement obtained by employing such multiscale representation, in representing shapes as well as the overall shape based segmentation tasks. [Copyright &y& Elsevier]

Published

2012