Your search keyword '"Moreno-Noguer, Francesc"' showing total 51 results

1. Simultaneous completion and spatiotemporal grouping of corrupted motion tracks.

Author

Agudo, Antonio, Lepetit, Vincent, and Moreno-Noguer, Francesc

Subjects

LOW-rank matrices, POLYNOMIAL time algorithms, LAGRANGE multiplier, POINT set theory

Abstract

Given an unordered list of 2D or 3D point trajectories corrupted by noise and partial observations, in this paper we introduce a framework to simultaneously recover the incomplete motion tracks and group the points into spatially and temporally coherent clusters. This advances existing work, which only addresses partial problems and without considering a unified and unsupervised solution. We cast this problem as a matrix completion one, in which point tracks are arranged into a matrix with the missing entries set as zeros. In order to perform the double clustering, the measurement matrix is assumed to be drawn from a dual union of spatiotemporal subspaces. The bases and the dimensionality for these subspaces, the affinity matrices used to encode the temporal and spatial clusters to which each point belongs, and the non-visible tracks, are then jointly estimated via augmented Lagrange multipliers in polynomial time. A thorough evaluation on incomplete motion tracks for multiple-object typologies shows that the accuracy of the matrix we recover compares favorably to that obtained with existing low-rank matrix completion methods, specially under noisy measurements. In addition, besides recovering the incomplete tracks, the point trajectories are directly grouped into different object instances, and a number of semantically meaningful temporal primitive actions are automatically discovered. [ABSTRACT FROM AUTHOR]

Published

2022

2. 3D Human Pose, Shape and Texture From Low-Resolution Images and Videos.

Author

Xu, Xiangyu, Chen, Hao, Moreno-Noguer, Francesc, Jeni, Laszlo A., and De la Torre, Fernando

Subjects

POSE estimation (Computer vision), VIDEO surveillance, TELEVISED sports, COMPUTER vision, DEEP learning, SPORTS films

Abstract

3D human pose and shape estimation from monocular images has been an active research area in computer vision. Existing deep learning methods for this task rely on high-resolution input, which however, is not always available in many scenarios such as video surveillance and sports broadcasting. Two common approaches to deal with low-resolution images are applying super-resolution techniques to the input, which may result in unpleasant artifacts, or simply training one model for each resolution, which is impractical in many realistic applications. To address the above issues, this paper proposes a novel algorithm called RSC-Net, which consists of a Resolution-aware network, a Self-supervision loss, and a Contrastive learning scheme. The proposed method is able to learn 3D body pose and shape across different resolutions with one single model. The self-supervision loss enforces scale-consistency of the output, and the contrastive learning scheme enforces scale-consistency of the deep features. We show that both these new losses provide robustness when learning in a weakly-supervised manner. Moreover, we extend the RSC-Net to handle low-resolution videos and apply it to reconstruct textured 3D pedestrians from low-resolution input. Extensive experiments demonstrate that the RSC-Net can achieve consistently better results than the state-of-the-art methods for challenging low-resolution images. [ABSTRACT FROM AUTHOR]

Published

2022

3. Dual-Branch CNNs for Vehicle Detection and Tracking on LiDAR Data.

Author

Vaquero, Victor, del Pino, Ivan, Moreno-Noguer, Francesc, Sola, Joan, Sanfeliu, Alberto, and Andrade-Cetto, Juan

Abstract

We present a novel vehicle detection and tracking system that works solely on 3D LiDAR information. Our approach segments vehicles using a dual-view representation of the 3D LiDAR point cloud on two independently trained convolutional neural networks, one for each view. A bounding box growing algorithm is applied to the fused output of the networks to properly enclose the segmented vehicles. Bounding boxes are grown using a probabilistic method that takes into account also occluded areas. The final vehicle bounding boxes act as observations for a multi-hypothesis tracking system which allows to estimate the position and velocity of the observed vehicles. We thoroughly evaluate our system on the KITTI benchmarks both for detection and tracking separately and show that our dual-branch classifier consistently outperforms previous single-branch approaches, improving or directly competing to other state of the art LiDAR-based methods. [ABSTRACT FROM AUTHOR]

Published

2021

4. GANimation: One-Shot Anatomically Consistent Facial Animation.

Author

Pumarola, Albert, Agudo, Antonio, Martinez, Aleix M., Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Subjects

FACIAL expression, HUMAN mechanics, IMAGE processing, MODEL railroads, FACIAL muscles, MUSCLE growth

Abstract

Recent advances in generative adversarial networks (GANs) have shown impressive results for the task of facial expression synthesis. The most successful architecture is StarGAN (Choi et al. in CVPR, 2018), that conditions GANs' generation process with images of a specific domain, namely a set of images of people sharing the same expression. While effective, this approach can only generate a discrete number of expressions, determined by the content and granularity of the dataset. To address this limitation, in this paper, we introduce a novel GAN conditioning scheme based on action units (AU) annotations, which describes in a continuous manifold the anatomical facial movements defining a human expression. Our approach allows controlling the magnitude of activation of each AU and combining several of them. Additionally, we propose a weakly supervised strategy to train the model, that only requires images annotated with their activated AUs, and exploit a novel self-learned attention mechanism that makes our network robust to changing backgrounds, lighting conditions and occlusions. Extensive evaluation shows that our approach goes beyond competing conditional generators both in the capability to synthesize a much wider range of expressions ruled by anatomically feasible muscle movements, as in the capacity of dealing with images in the wild. The code of this work is publicly available at https://github.com/albertpumarola/GANimation. [ABSTRACT FROM AUTHOR]

Published

2020

5. Robust Spatio-Temporal Clustering and Reconstruction of Multiple Deformable Bodies.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Subjects

ROBUST control, AUTOMATIC control systems, CONTROL theory (Engineering), CLUSTERING of particles, COAGULATION

Abstract

In this paper we present an approach to reconstruct the 3D shape of multiple deforming objects from a collection of sparse, noisy and possibly incomplete 2D point tracks acquired by a single monocular camera. Additionally, the proposed solution estimates the camera motion and reasons about the spatial segmentation (i.e., identifies each of the deforming objects in every frame) and temporal clustering (i.e., splits the sequence into motion primitive actions). This advances competing work, which mainly tackled the problem for one single object and non-occluded tracks. In order to handle several objects at a time from partial observations, we model point trajectories as a union of spatial and temporal subspaces, and optimize the parameters of both modalities, the non-observed point tracks, the camera motion, and the time-varying 3D shape via augmented Lagrange multipliers. The algorithm is fully unsupervised and does not require any training data at all. We thoroughly validate the method on challenging scenarios with several human subjects performing different activities which involve complex motions and close interaction. We show our approach achieves state-of-the-art 3D reconstruction results, while it also provides spatial and temporal segmentation. [ABSTRACT FROM AUTHOR]

Published

2019

6. Shape Basis Interpretation for Monocular Deformable 3-D Reconstruction.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Abstract

In this paper, we propose a novel interpretable shape model to encode object nonrigidity. We first use the initial frames of a monocular video to recover a rest shape, used later to compute a dissimilarity measure based on a distance matrix measurement. Spectral analysis is then applied to this matrix to obtain a reduced shape basis, that in contrast to existing approaches, can be physically interpreted. In turn, these precomputed shape bases are used to linearly span the deformation of a wide variety of objects. We introduce the low-rank basis into a sequential approach to recover both camera motion and nonrigid shape from the monocular video, by simply optimizing the weights of the linear combination using bundle adjustment. Since the number of parameters to optimize per frame is relatively small, specially when physical priors are considered, our approach is fast and can potentially run in real time. Validation is done in a wide variety of real-world objects, undergoing both inextensible and extensible deformations. Our approach achieves remarkable robustness to artifacts such as noisy and missing measurements and shows an improved performance to competing methods. [ABSTRACT FROM AUTHOR]

Published

2019

7. Online learning and detection of faces with low human supervision.

Author

Villamizar, Michael, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Subjects

FACE, ONLINE education, MACHINE learning

Abstract

We present an efficient, online, and interactive approach for computing a classifier, called Wild Lady Ferns (WiLFs), for face learning and detection using small human supervision. More precisely, on the one hand, WiLFs combine online boosting and extremely randomized trees (random ferns) to compute progressively an efficient and discriminative classifier. On the other hand, WiLFs use an interactive human-machine approach that combines two complementary learning strategies to reduce considerably the degree of human supervision during learning. While the first strategy corresponds to query-by-boosting active learning, that requests human assistance over difficult samples in function of the classifier confidence, the second strategy refers to a memory-based learning which uses κ exemplar-based nearest neighbors (κENN) to assist automatically the classifier. A pretrained convolutional neural network is used to perform κENN with high-level feature descriptors. The proposed approach is therefore fast (WilFs run in 1 FPS using a code not fully optimized), accurate (we obtain detection rates over 82% in complex datasets), and labor-saving (human assistance percentages of less than 20%). As a by-product, we demonstrate that WiLFs also perform semiautomatic annotation during learning, as while the classifier is being computed, WiLFs are discovering faces instances in input images which are used subsequently for training online the classifier. The advantages of our approach are demonstrated in synthetic and publicly available databases, showing comparable detection rates as offline approaches that require larger amounts of handmade training data. [ABSTRACT FROM AUTHOR]

Published

2019

8. Force-Based Representation for Non-Rigid Shape and Elastic Model Estimation.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Subjects

VISUAL perception, IMAGE processing, COMPUTER graphics, IMAGE recognition (Computer vision), MULTIPLE correspondence analysis (Statistics)

Abstract

This paper addresses the problem of simultaneously recovering 3D shape, pose and the elastic model of a deformable object from only 2D point tracks in a monocular video. This is a severely under-constrained problem that has been typically addressed by enforcing the shape or the point trajectories to lie on low-rank dimensional spaces. We show that formulating the problem in terms of a low-rank force space that induces the deformation and introducing the elastic model as an additional unknown, allows for a better physical interpretation of the resulting priors and a more accurate representation of the actual object’s behavior. In order to simultaneously estimate force, pose, and the elastic model of the object we use an expectation maximization strategy, where each of these parameters are successively learned by partial M-steps. Once the elastic model is learned, it can be transfered to similar objects to code its 3D deformation. Moreover, our approach can robustly deal with missing data, and encode both rigid and non-rigid points under the same formalism. We thoroughly validate the approach on Mocap and real sequences, showing more accurate 3D reconstructions than state-of-the-art, and additionally providing an estimate of the full elastic model with no a priori information. [ABSTRACT FROM AUTHOR]

Published

2018

9. BreakingNews: Article Annotation by Image and Text Processing.

Author

Ramisa, Arnau, Yan, Fei, Moreno-Noguer, Francesc, and Mikolajczyk, Krystian

Subjects

TEXT processing (Computer science), ARTIFICIAL neural networks, DEEP learning, NATURAL language processing, DATA visualization, GLOBAL Positioning System

Abstract

Building upon recent Deep Neural Network architectures, current approaches lying in the intersection of Computer Vision and Natural Language Processing have achieved unprecedented breakthroughs in tasks like automatic captioning or image retrieval. Most of these learning methods, though, rely on large training sets of images associated with human annotations that specifically describe the visual content. In this paper we propose to go a step further and explore the more complex cases where textual descriptions are loosely related to the images. We focus on the particular domain of news articles in which the textual content often expresses connotative and ambiguous relations that are only suggested but not directly inferred from images. We introduce an adaptive CNN architecture that shares most of the structure for multiple tasks including source detection, article illustration and geolocation of articles. Deep Canonical Correlation Analysis is deployed for article illustration, and a new loss function based on Great Circle Distance is proposed for geolocation. Furthermore, we present BreakingNews, a novel dataset with approximately 100K news articles including images, text and captions, and enriched with heterogeneous meta-data (such as GPS coordinates and user comments). We show this dataset to be appropriate to explore all aforementioned problems, for which we provide a baseline performance using various Deep Learning architectures, and different representations of the textual and visual features. We report very promising results and bring to light several limitations of current state-of-the-art in this kind of domain, which we hope will help spur progress in the field. [ABSTRACT FROM PUBLISHER]

Published

2018

10. Boosted Random Ferns for Object Detection.

Author

Vergel, Michael Villamizar, Andrade-Cetto, Juan, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Subjects

OBJECT recognition (Computer vision), HISTOGRAMS, BOOSTING algorithms, THREE-dimensional imaging, FEATURE extraction

Abstract

In this paper we introduce the Boosted Random Ferns (BRFs) to rapidly build discriminative classifiers for learning and detecting object categories. At the core of our approach we use standard random ferns, but we introduce four main innovations that let us bring ferns from an instance to a category level, and still retain efficiency. First, we define binary features on the histogram of oriented gradients-domain (as opposed to intensity-), allowing for a better representation of intra-class variability. Second, both the positions where ferns are evaluated within the sliding window, and the location of the binary features for each fern are not chosen completely at random, but instead we use a boosting strategy to pick the most discriminative combination of them. This is further enhanced by our third contribution, that is to adapt the boosting strategy to enable sharing of binary features among different ferns, yielding high recognition rates at a low computational cost. And finally, we show that training can be performed online, for sequentially arriving images. Overall, the resulting classifier can be very efficiently trained, densely evaluated for all image locations in about 0.1 seconds, and provides detection rates similar to competing approaches that require expensive and significantly slower processing times. We demonstrate the effectiveness of our approach by thorough experimentation in publicly available datasets in which we compare against state-of-the-art, and for tasks of both 2D detection and 3D multi-view estimation. [ABSTRACT FROM PUBLISHER]

Published

2018

11. Accurate and Linear Time Pose Estimation from Points and Lines.

Author

Vakhitov, Alexander, Funke, Jan, and Moreno-Noguer, Francesc

Published

2016

12. Mode-shape interpretation: Re-thinking modal space for recovering deformable shapes.

Author

Agudo, Antonio, Montiel, J. M. M., Calvo, Begona, and Moreno-Noguer, Francesc

Published

2016

13. Dense Segmentation-Aware Descriptors.

Author

Trulls, Eduard, Kokkinos, Iasonas, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Published

2016

14. 3D Human Pose Tracking Priors using Geodesic Mixture Models.

Author

Simo-Serra, Edgar, Torras, Carme, and Moreno-Noguer, Francesc

Subjects

RIEMANNIAN manifolds, EUCLIDEAN metric, EXPECTATION-maximization algorithms, GEODESIC distance, PROBABILISTIC generative models, HUMAN kinematics

Abstract

We present a novel approach for learning a finite mixture model on a Riemannian manifold in which Euclidean metrics are not applicable and one needs to resort to geodesic distances consistent with the manifold geometry. For this purpose, we draw inspiration on a variant of the expectation-maximization algorithm, that uses a minimum message length criterion to automatically estimate the optimal number of components from multivariate data lying on an Euclidean space. In order to use this approach on Riemannian manifolds, we propose a formulation in which each component is defined on a different tangent space, thus avoiding the problems associated with the loss of accuracy produced when linearizing the manifold with a single tangent space. Our approach can be applied to any type of manifold for which it is possible to estimate its tangent space. Additionally, we consider using shrinkage covariance estimation to improve the robustness of the method, especially when dealing with very sparsely distributed samples. We evaluate the approach on a number of situations, going from data clustering on manifolds to combining pose and kinematics of articulated bodies for 3D human pose tracking. In all cases, we demonstrate remarkable improvement compared to several chosen baselines. [ABSTRACT FROM AUTHOR]

Published

2017

15. Combining Local-Physical and Global-Statistical Models for Sequential Deformable Shape from Motion.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Subjects

SEQUENTIAL pattern mining, NEWTON'S laws of motion, PARTICLE dynamics analysis, THREE-dimensional imaging, IMAGE reconstruction

Abstract

In this paper, we simultaneously estimate camera pose and non-rigid 3D shape from a monocular video, using a sequential solution that combines local and global representations. We model the object as an ensemble of particles, each ruled by the linear equation of the Newton's second law of motion. This dynamic model is incorporated into a bundle adjustment framework, in combination with simple regularization components that ensure temporal and spatial consistency. The resulting approach allows to sequentially estimate shape and camera poses, while progressively learning a global low-rank model of the shape that is fed back into the optimization scheme, introducing thus, global constraints. The overall combination of local (physical) and global (statistical) constraints yields a solution that is both efficient and robust to several artifacts such as noisy and missing data or sudden camera motions, without requiring any training data at all. Validation is done in a variety of real application domains, including articulated and non-rigid motion, both for continuous and discontinuous shapes. Our on-line methodology yields significantly more accurate reconstructions than competing sequential approaches, being even comparable to the more computationally demanding batch methods. [ABSTRACT FROM AUTHOR]

Published

2017

16. A High Performance CRF Model for Clothes Parsing.

Author

Simo-Serra, Edgar, Fidler, Sanja, Moreno-Noguer, Francesc, and Urtasun, Raquel

Published

2015

17. Simultaneous pose and non-rigid shape with particle dynamics.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Published

2015

18. Neuroaesthetics in fashion: Modeling the perception of fashionability.

Author

Simo-Serra, Edgar, Fidler, Sanja, Moreno-Noguer, Francesc, and Urtasun, Raquel

Published

2015

19. Learning Shape, Motion and Elastic Models in Force Space.

Author

Agudo, Antonio and Moreno-Noguer, Francesc

Published

2015

20. Discriminative Learning of Deep Convolutional Feature Point Descriptors.

Author

Simo-Serra, Edgar, Trulls, Eduard, Ferraz, Luis, Kokkinos, Iasonas, Fua, Pascal, and Moreno-Noguer, Francesc

Published

2015

21. Matchability Prediction for Full-Search Template Matching Algorithms.

Author

Penate-Sanchez, Adrian, Porzi, Lorenzo, and Moreno-Noguer, Francesc

Published

2015

22. Lie Algebra-Based Kinematic Prior for 3D Human Pose Tracking.

Author

Simo-Serra, Edgar, Torras, Carme, and Moreno-Noguer, Francesc

Published

2015

23. Sequential Non-Rigid Structure from Motion Using Physical Priors.

Author

Agudo, Antonio, Moreno-Noguer, Francesc, Calvo, Begona, and Montiel, Jose M. Martinez

Subjects

CAMERAS, POSE estimation (Computer vision), THREE-dimensional imaging, FINITE element method, ISOMETRICS (Mathematics), KALMAN filtering

Abstract

We propose a new approach to simultaneously recover camera pose and 3D shape of non-rigid and potentially extensible surfaces from a monocular image sequence. For this purpose, we make use of the Extended Kalman Filter based Simultaneous Localization And Mapping (EKF-SLAM) formulation, a Bayesian optimization framework traditionally used in mobile robotics for estimating camera pose and reconstructing rigid scenarios. In order to extend the problem to a deformable domain we represent the object's surface mechanics by means of Navier's equations, which are solved using a Finite Element Method (FEM). With these main ingredients, we can further model the material's stretching, allowing us to go a step further than most of current techniques, typically constrained to surfaces undergoing isometric deformations. We extensively validate our approach in both real and synthetic experiments, and demonstrate its advantages with respect to competing methods. More specifically, we show that besides simultaneously retrieving camera pose and non-rigid shape, our approach is adequate for both isometric and extensible surfaces, does not require neither batch processing all the frames nor tracking points over the whole sequence and runs at several frames per second. [ABSTRACT FROM PUBLISHER]

Published

2016

24. MSClique: Multiple Structure Discovery through the Maximum Weighted Clique Problem.

Author

Sanroma, Gerard, Penate-Sanchez, Adrian, Alquézar, René, Serratosa, Francesc, Moreno-Noguer, Francesc, Andrade-Cetto, Juan, and González Ballester, Miguel Ángel

Subjects

CLIQUES (Sociology), COMPUTER vision, AGGLOMERATION (Materials), MACHINE-shop practice, OUTLIERS (Statistics)

Abstract

We present a novel approach for feature correspondence and multiple structure discovery in computer vision. In contrast to existing methods, we exploit the fact that point-sets on the same structure usually lie close to each other, thus forming clusters in the image. Given a pair of input images, we initially extract points of interest and extract hierarchical representations by agglomerative clustering. We use the maximum weighted clique problem to find the set of corresponding clusters with maximum number of inliers representing the multiple structures at the correct scales. Our method is parameter-free and only needs two sets of points along with their tentative correspondences, thus being extremely easy to use. We demonstrate the effectiveness of our method in multiple-structure fitting experiments in both publicly available and in-house datasets. As shown in the experiments, our approach finds a higher number of structures containing fewer outliers compared to state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2016

25. Very Fast Solution to the PnP Problem with Algebraic Outlier Rejection.

Author

Ferraz, Luis, Binefa, Xavier, and Moreno-Noguer, Francesc

Published

2014

26. Segmentation-Aware Deformable Part Models.

Author

Trulls, Eduard, Tsogkas, Stavros, Kokkinos, Iasonas, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Published

2014

27. On-board real-time pose estimation for UAVs using deformable visual contour registration.

Author

Amor-Martinez, Adrian, Ruiz, Alberto, Moreno-Noguer, Francesc, and Sanfeliu, Alberto

Published

2014

28. LETHA: Learning from High Quality Inputs for 3D Pose Estimation in Low Quality Images.

Author

Penate-Sanchez, Adrian, Moreno-Noguer, Francesc, Andrade-Cetto, Juan, and Fleuret, Francois

Published

2014

29. DaLI: Deformation and Light Invariant Descriptor.

Author

Simo-Serra, Edgar, Torras, Carme, and Moreno-Noguer, Francesc

Subjects

HEAT, KERNEL operating systems, KERNEL functions, COMPLEX variables, LOGARITHMS

Abstract

Recent advances in 3D shape analysis and recognition have shown that heat diffusion theory can be effectively used to describe local features of deforming and scaling surfaces. In this paper, we show how this description can be used to characterize 2D image patches, and introduce DaLI, a novel feature point descriptor with high resilience to non-rigid image transformations and illumination changes. In order to build the descriptor, 2D image patches are initially treated as 3D surfaces. Patches are then described in terms of a heat kernel signature, which captures both local and global information, and shows a high degree of invariance to non-linear image warps. In addition, by further applying a logarithmic sampling and a Fourier transform, invariance to photometric changes is achieved. Finally, the descriptor is compacted by mapping it onto a low dimensional subspace computed using Principal Component Analysis, allowing for an efficient matching. A thorough experimental validation demonstrates that DaLI is significantly more discriminative and robust to illuminations changes and image transformations than state of the art descriptors, even those specifically designed to describe non-rigid deformations. [ABSTRACT FROM AUTHOR]

Published

2015

30. Non-Rigid Graph Registration Using Active Testing Search.

Author

Serradell, Eduard, Pinheiro, Miguel Amavel, Sznitman, Raphael, Kybic, Jan, Moreno-Noguer, Francesc, and Fua, Pascal

Subjects

IMAGE registration, PATTERN matching, DIGITAL image processing, PATTERN recognition systems, GAUSSIAN processes, THREE-dimensional imaging, MEDICAL imaging systems, ARTIFICIAL intelligence

Abstract

We present a new approach for matching sets of branching curvilinear structures that form graphs embedded in \mathbb R^2 or \mathbb R^3 and may be subject to deformations. Unlike earlier methods, ours does not rely on local appearance similarity nor does require a good initial alignment. Furthermore, it can cope with non-linear deformations, topological differences, and partial graphs. To handle arbitrary non-linear deformations, we use Gaussian process regressions to represent the geometrical mapping relating the two graphs. In the absence of appearance information, we iteratively establish correspondences between points, update the mapping accordingly, and use it to estimate where to find the most likely correspondences that will be used in the next step. To make the computation tractable for large graphs, the set of new potential matches considered at each iteration is not selected at random as with many RANSAC-based algorithms. Instead, we introduce a so-called Active Testing Search strategy that performs a priority search to favor the most likely matches and speed-up the process. We demonstrate the effectiveness of our approach first on synthetic cases and then on angiography data, retinal fundus images, and microscopy image stacks acquired at very different resolutions. [ABSTRACT FROM PUBLISHER]

Published

2015

31. A Joint Model for 2D and 3D Pose Estimation from a Single Image.

Author

Simo-Serra, Edgar, Quattoni, Ariadna, Torras, Carme, and Moreno-Noguer, Francesc

Published

2013

32. Dense Segmentation-Aware Descriptors.

Author

Trulls, Eduard, Kokkinos, Iasonas, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Published

2013

33. Active Testing Search for Point Cloud Matching.

Author

Pinheiro, Miguel Amável, Sznitman, Raphael, Serradell, Eduard, Kybic, Jan, Moreno-Noguer, Francesc, and Fua, Pascal

Published

2013

34. FINDDD: A fast 3D descriptor to characterize textiles for robot manipulation.

Author

Ramisa, Arnau, Alenya, Guillem, Moreno-Noguer, Francesc, and Torras, Carme

Abstract

Most current depth sensors provide 2.5D range images in which depth values are assigned to a rectangular 2D array. In this paper we take advantage of this structured information to build an efficient shape descriptor which is about two orders of magnitude faster than competing approaches, while showing similar performance in several tasks involving deformable object recognition. Given a 2D patch surrounding a point and its associated depth values, we build the descriptor for that point, based on the cumulative distances between their normals and a discrete set of normal directions. This processing is made very efficient using integral images, even allowing to compute descriptors for every range image pixel in a few seconds. The discriminative power of our descriptor, dubbed FINDDD, is evaluated in three different scenarios: recognition of specific cloth wrinkles, instance recognition from geometry alone, and detection of reliable and informed grasping points. [ABSTRACT FROM PUBLISHER]

Published

2013

35. Spatiotemporal Descriptor for Wide-Baseline Stereo Reconstruction of Non-rigid and Ambiguous Scenes.

Author

Trulls, Eduard, Sanfeliu, Alberto, and Moreno-Noguer, Francesc

Published

2012

36. Using depth and appearance features for informed robot grasping of highly wrinkled clothes.

Author

Ramisa, Arnau, Alenya, Guillem, Moreno-Noguer, Francesc, and Torras, Carme

Abstract

Detecting grasping points is a key problem in cloth manipulation. Most current approaches follow a multiple re-grasp strategy for this purpose, in which clothes are sequentially grasped from different points until one of them yields to a desired configuration. In this paper, by contrast, we circumvent the need for multiple re-graspings by building a robust detector that identifies the grasping points, generally in one single step, even when clothes are highly wrinkled. [ABSTRACT FROM PUBLISHER]

Published

2012

37. Robust non-rigid registration of 2D and 3D graphs.

Author

Serradell, Eduard, Glowacki, Przemyslaw, Kybic, Jan, Moreno-Noguer, Francesc, and Fua, Pascal

Abstract

We present a new approach to matching graphs embedded in R2 or R3. Unlike earlier methods, our approach does not rely on the similarity of local appearance features, does not require an initial alignment, can handle partial matches, and can cope with non-linear deformations and topological differences. To handle arbitrary non-linear deformations, we represent them as Gaussian Processes. In the absence of appearance information, we iteratively establish correspondences between graph nodes, update the structure accordingly, and use the current mapping estimate to find the most likely correspondences that will be used in the next iteration. This makes the computation tractable. We demonstrate the effectiveness of our approach first on synthetic cases and then on angiography data, retinal fundus images, and microscopy image stacks acquired at very different resolutions. [ABSTRACT FROM PUBLISHER]

Published

2012

38. Simultaneous correspondence and non-rigid 3D reconstruction of the coronary tree from single X-ray images.

Author

Serradell, Eduard, Romero, Adriana, Leta, Ruben, Gatta, Carlo, and Moreno-Noguer, Francesc

Published

2011

39. Combining Geometric and Appearance Priors for Robust Homography Estimation.

Author

Serradell, Eduard, Özuysal, Mustafa, Lepetit, Vincent, Fua, Pascal, and Moreno-Noguer, Francesc

Abstract

The homography between pairs of images are typically computed from the correspondence of keypoints, which are established by using image descriptors. When these descriptors are not reliable, either because of repetitive patterns or large amounts of clutter, additional priors need to be considered. The Blind PnP algorithm makes use of geometric priors to guide the search for matches while computing camera pose. Inspired by this, we propose a novel approach for homography estimation that combines geometric priors with appearance priors of ambiguous descriptors. More specifically, for each point we retain its best candidates according to appearance. We then prune the set of potential matches by iteratively shrinking the regions of the image that are consistent with the geometric prior. We can then successfully compute homographies between pairs of images containing highly repetitive patterns and even under oblique viewing conditions. [ABSTRACT FROM AUTHOR]

Published

2010

40. Exploring Ambiguities for Monocular Non-rigid Shape Estimation.

Author

Moreno-Noguer, Francesc, Porta, Josep M., and Fua, Pascal

Abstract

Recovering the 3D shape of deformable surfaces from single images is difficult because many different shapes have very similar projections. This is commonly addressed by restricting the set of possible shapes to linear combinations of deformation modes and by imposing additional geometric constraints. Unfortunately, because image measurements are noisy, such constraints do not always guarantee that the correct shape will be recovered. To overcome this limitation, we introduce an efficient approach to exploring the set of solutions of an objective function based on point-correspondences and to proposing a small set of candidate 3D shapes. This allows the use of additional image information to choose the best one. As a proof of concept, we use either motion or shading cues to this end and show that we can handle a complex objective function without having to solve a difficult non-linear minimization problem. [ABSTRACT FROM AUTHOR]

Published

2010

41. Closed-Form Solution to Non-rigid 3D Surface Registration.

Author

Salzmann, Mathieu, Moreno-Noguer, Francesc, Lepetit, Vincent, and Fua, Pascal

Abstract

We present a closed-form solution to the problem of recovering the 3D shape of a non-rigid inelastic surface from 3D-to-2D correspondences. This lets us detect and reconstruct such a surface by matching individual images against a reference configuration, which is in contrast to all existing approaches that require initial shape estimates and track deformations from image to image. We represent the surface as a mesh, and write the constraints provided by the correspondences as a linear system whose solution we express as a weighted sum of eigenvectors. Obtaining the weights then amounts to solving a set of quadratic equations accounting for inextensibility constraints between neighboring mesh vertices. Since available closed-form solutions to quadratic systems fail when there are too many variables, we reduce the number of unknowns by expressing the deformations as a linear combination of modes. The overall closed-form solution then becomes tractable even for complex deformations that require many modes. [ABSTRACT FROM AUTHOR]

Published

2008

42. Pose Priors for Simultaneously Solving Alignment and Correspondence.

Author

Moreno-Noguer, Francesc, Lepetit, Vincent, and Fua, Pascal

Abstract

Estimating a camera pose given a set of 3D-object and 2D-image feature points is a well understood problem when correspondences are given. However, when such correspondences cannot be established a priori, one must simultaneously compute them along with the pose. Most current approaches to solving this problem are too computationally intensive to be practical. An interesting exception is the SoftPosit algorithm, that looks for the solution as the minimum of a suitable objective function. It is arguably one of the best algorithms but its iterative nature means it can fail in the presence of clutter, occlusions, or repetitive patterns. In this paper, we propose an approach that overcomes this limitation by taking advantage of the fact that, in practice, some prior on the camera pose is often available. We model it as a Gaussian Mixture Model that we progressively refine by hypothesizing new correspondences. This rapidly reduces the number of potential matches for each 3D point and lets us explore the pose space more thoroughly than SoftPosit at a similar computational cost. We will demonstrate the superior performance of our approach on both synthetic and real data. [ABSTRACT FROM AUTHOR]

Published

2008

43. A Framework to Integrate Particle Filters for Robust Tracking in Non-stationary Environments.

Author

Marques, Jorge S., Pérez de la Blanca, Nicolás, Pina, Pedro, Moreno-Noguer, Francesc, and Sanfeliu, Alberto

Abstract

In this paper we propose a new framework to integrate several particle filters, in order to obtain a robust tracking system able to cope with abrupt changes of illumination and position of the target. The proposed method is analytically justified and allows to build a tracking procedure that adapts online and simultaneously the colorspace where the image points are represented, the color distributions of the object and background and the contour of the object. [ABSTRACT FROM AUTHOR]

Published

2005

44. Exhaustive Linearization for Robust Camera Pose and Focal Length Estimation.

Author

Penate-Sanchez, Adrian, Andrade-Cetto, Juan, and Moreno-Noguer, Francesc

Subjects

ELECTRONIC linearization, CALIBRATION, FOCAL length, LEAST squares, QUADRATIC equations, SINGULAR value decomposition

Abstract

We propose a novel approach for the estimation of the pose and focal length of a camera from a set of 3D-to-2D point correspondences. Our method compares favorably to competing approaches in that it is both more accurate than existing closed form solutions, as well as faster and also more accurate than iterative ones. Our approach is inspired on the EPnP algorithm, a recent O(n) solution for the calibrated case. Yet we show that considering the focal length as an additional unknown renders the linearization and relinearization techniques of the original approach no longer valid, especially with large amounts of noise. We present new methodologies to circumvent this limitation termed exhaustive linearization and exhaustive relinearization which perform a systematic exploration of the solution space in closed form. The method is evaluated on both real and synthetic data, and our results show that besides producing precise focal length estimation, the retrieved camera pose is almost as accurate as the one computed using the EPnP, which assumes a calibrated camera. [ABSTRACT FROM AUTHOR]

Published

2013

45. Stochastic Exploration of Ambiguities for Nonrigid Shape Recovery.

Author

Moreno-Noguer, Francesc and Fua, Pascal

Subjects

GEOMETRIC shapes, STOCHASTIC analysis, STOCHASTIC processes, MATHEMATICAL analysis, GEOMETRIC surfaces

Abstract

Recovering the 3D shape of deformable surfaces from single images is known to be a highly ambiguous problem because many different shapes may have very similar projections. This is commonly addressed by restricting the set of possible shapes to linear combinations of deformation modes and by imposing additional geometric constraints. Unfortunately, because image measurements are noisy, such constraints do not always guarantee that the correct shape will be recovered. To overcome this limitation, we introduce a stochastic sampling approach to efficiently explore the set of solutions of an objective function based on point correspondences. This allows us to propose a small set of ambiguous candidate 3D shapes and then use additional image information to choose the best one. As a proof of concept, we use either motion or shading cues to this end and show that we can handle a complex objective function without having to solve a difficult nonlinear minimization problem. The advantages of our method are demonstrated on a variety of problems including both real and synthetic data. [ABSTRACT FROM AUTHOR]

Published

2013

46. EP nP: An Accurate O( n) Solution to the P nP Problem.

Author

Lepetit, Vincent, Moreno-Noguer, Francesc, and Fua, Pascal

Subjects

COMPUTATIONAL complexity, COMPUTER vision, THREE-dimensional imaging, MATRICES (Mathematics), MACHINE theory, EIGENVECTORS

Abstract

We propose a non-iterative solution to the P nP problem—the estimation of the pose of a calibrated camera from n 3D-to-2D point correspondences—whose computational complexity grows linearly with n. This is in contrast to state-of-the-art methods that are O( n 5) or even O( n 8), without being more accurate. Our method is applicable for all n≥4 and handles properly both planar and non-planar configurations. Our central idea is to express the n 3D points as a weighted sum of four virtual control points. The problem then reduces to estimating the coordinates of these control points in the camera referential, which can be done in O( n) time by expressing these coordinates as weighted sum of the eigenvectors of a 12×12 matrix and solving a small constant number of quadratic equations to pick the right weights. Furthermore, if maximal precision is required, the output of the closed-form solution can be used to initialize a Gauss-Newton scheme, which improves accuracy with negligible amount of additional time. The advantages of our method are demonstrated by thorough testing on both synthetic and real-data. [ABSTRACT FROM AUTHOR]

Published

2009

47. Dependent Multiple Cue Integration for Robust Tracking.

Author

Moreno-Noguer, Francesc, Sanfeliu, Alberto, and Samaras, Dimitris

Subjects

BAYESIAN analysis, KALMAN filtering, ROBUST control, PATTERN recognition systems, MACHINE learning, ARTIFICIAL intelligence

Abstract

We propose a new technique for fusing multiple cues to robustly segment an object from its background in video sequences that suffer from abrupt changes of both illumination and position of the target. Robustness is achieved by the integration of appearance and geometric object features and by their estimation using Bayesian filters, such as Kalman or particle filters. In particular, each filter estimates the state of a specific object feature, conditionally dependent on another feature estimated by a distinct filter. This dependence provides improved target representations, permitting us to segment it out from the background even in nonstationary sequences. Considering that the procedure of the Bayesian filters may be described by a "hypotheses generation-hypotheses correction" strategy, the major novelty of our methodology compared to previous approaches is that the mutual dependence between filters is considered during the feature observation, that is, into the "hypotheses-correction" stage, instead of considering it when generating the hypotheses. This proves to be much more effective in terms of accuracy and reliability. The proposed method is analytically justified and applied to develop a robust tracking system that adapts online and simultaneously the color space where the image points are represented, the color distributions, the contour of the object, and its bounding box. Results with synthetic data and real video sequences demonstrate the robustness and versatility of our method. [ABSTRACT FROM AUTHOR]

Published

2008

48. Active Refocusing of Images and Videos.

Author

Moreno-Noguer, Francesc, Belhumeur, Peter N., and Nayar, Shree K.

Subjects

GRAPHIC arts, COMPUTER graphics research, INTERNET resources in photography, THREE-dimensional imaging, IMAGE processing, COMPUTER vision

Abstract

We present a system for refocusing images and videos of dynamic scenes using a novel, single-view depth estimation method. Our method for obtaining depth is based on the defocus of a sparse set of dots projected onto the scene. In contrast to other active illu- mination techniques, the projected pattern of dots can be removed from each captured image and its brightness easily controlled in or- der to avoid under- or over-exposure. The depths corresponding to the projected dots and a color segmentation of the image are used to compute an approximate depth map of the scene with clean region boundaries. The depth map is used to refocus the acquired image after the dots are removed, simulating realistic depth of field effects. Experiments on a wide variety of scenes, including close-ups and live action, demonstrate the effectiveness of our method. [ABSTRACT FROM AUTHOR]

Published

2007

49. The Influence of Camera Calibration on Nearshore Bathymetry Estimation from UAV Videos.

Author

Simarro, Gonzalo, Calvete, Daniel, Plomaritis, Theocharis A., Moreno-Noguer, Francesc, Giannoukakou-Leontsini, Ifigeneia, Montes, Juan, and Durán, Ruth

Subjects

CAMERA calibration, BATHYMETRY, STANDARD deviations, IMAGE stabilization, COASTAL zone management, CAMERAS, DRONE aircraft

Abstract

Measuring the nearshore bathymetry is critical in coastal management and morphodynamic studies. The recent advent of Unmanned Aerial Vehicles (UAVs), in combination with coastal video monitoring techniques, allows for an alternative and low cost evaluation of the nearshore bathymetry. Camera calibration and stabilization is a critical issue in bathymetry estimation from video systems. This work introduces a new methodology in order to obtain such bathymetries, and it compares the results to echo-sounder ground truth data. The goal is to gain a better understanding on the influence of the camera calibration and stabilization on the inferred bathymetry. The results show how the proposed methodology allows for accurate evaluations of the bathymetry, with overall root mean square errors in the order of 40 cm. It is shown that the intrinsic calibration of the camera, related to the lens distortion, is the most critical aspect. Here, the intrinsic calibration that was obtained directly during the flight yields the best results. [ABSTRACT FROM AUTHOR]

Published

2021

50. Active refocusing of images and videos.

Author

Moreno-Noguer, Francesc, Belhumeur, Peter N., and Nayar, Shree K.

Published

2007