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1. SPIN: Spacecraft Imagery for Navigation

Author

Montalvo, Javier, Pérez-Villar, Juan Ignacio Bravo, García-Martín, Álvaro, Carballeira, Pablo, and Besc'os, Jesús

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Data acquired in space operational conditions is scarce due to the costs and complexity of space operations. This poses a challenge to learning-based visual-based navigation algorithms employed in autonomous spacecraft navigation. Existing datasets, which largely depend on computer-simulated data, have partially filled this gap. However, the image generation tools they use are proprietary, which limits the evaluation of methods to unseen scenarios. Furthermore, these datasets provide limited ground-truth data, primarily focusing on the spacecraft's translation and rotation relative to the camera. To address these limitations, we present SPIN (SPacecraft Imagery for Navigation), an open-source realistic spacecraft image generation tool for relative navigation between two spacecrafts. SPIN provides a wide variety of ground-truth data and allows researchers to employ custom 3D models of satellites, define specific camera-relative poses, and adjust various settings such as camera parameters and environmental illumination conditions. For the task of spacecraft pose estimation, we compare the results of training with a SPIN-generated dataset against existing synthetic datasets. We show a %50 average error reduction in common testbed data (that simulates realistic space conditions). Both the SPIN tool (and source code) and our enhanced version of the synthetic datasets will be publicly released upon paper acceptance on GitHub https://github.com/vpulab/SPIN.

Published
2024

4. Self-Supervised Curricular Deep Learning for Chest X-Ray Image Classification

Author

Tamé, Iván de Andrés, Sirotkin, Kirill, Carballeira, Pablo, and Escudero-Viñolo, Marcos

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Deep learning technologies have already demonstrated a high potential to build diagnosis support systems from medical imaging data, such as Chest X-Ray images. However, the shortage of labeled data in the medical field represents one key obstacle to narrow down the performance gap with respect to applications in other image domains. In this work, we investigate the benefits of a curricular Self-Supervised Learning (SSL) pretraining scheme with respect to fully-supervised training regimes for pneumonia recognition on Chest X-Ray images of Covid-19 patients. We show that curricular SSL pretraining, which leverages unlabeled data, outperforms models trained from scratch, or pretrained on ImageNet, indicating the potential of performance gains by SSL pretraining on massive unlabeled datasets. Finally, we demonstrate that top-performing SSLpretrained models show a higher degree of attention in the lung regions, embodying models that may be more robust to possible external confounding factors in the training datasets, identified by previous works.

Published
2023

5. A study on the distribution of social biases in self-supervised learning visual models

Author

Sirotkin, Kirill, Carballeira, Pablo, and Escudero-Viñolo, Marcos

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Deep neural networks are efficient at learning the data distribution if it is sufficiently sampled. However, they can be strongly biased by non-relevant factors implicitly incorporated in the training data. These include operational biases, such as ineffective or uneven data sampling, but also ethical concerns, as the social biases are implicitly present\textemdash even inadvertently, in the training data or explicitly defined in unfair training schedules. In tasks having impact on human processes, the learning of social biases may produce discriminatory, unethical and untrustworthy consequences. It is often assumed that social biases stem from supervised learning on labelled data, and thus, Self-Supervised Learning (SSL) wrongly appears as an efficient and bias-free solution, as it does not require labelled data. However, it was recently proven that a popular SSL method also incorporates biases. In this paper, we study the biases of a varied set of SSL visual models, trained using ImageNet data, using a method and dataset designed by psychological experts to measure social biases. We show that there is a correlation between the type of the SSL model and the number of biases that it incorporates. Furthermore, the results also suggest that this number does not strictly depend on the model's accuracy and changes throughout the network. Finally, we conclude that a careful SSL model selection process can reduce the number of social biases in the deployed model, whilst keeping high performance., Comment: 10 pages, 6 figures, accepted in CVPR2022

Published
2022

6. Graph Neural Networks for Cross-Camera Data Association

Author

Luna, Elena, SanMiguel, Juan C., Martínez, José M., and Carballeira, Pablo

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Cross-camera image data association is essential for many multi-camera computer vision tasks, such as multi-camera pedestrian detection, multi-camera multi-target tracking, 3D pose estimation, etc. This association task is typically stated as a bipartite graph matching problem and often solved by applying minimum-cost flow techniques, which may be computationally inefficient with large data. Furthermore, cameras are usually treated by pairs, obtaining local solutions, rather than finding a global solution at once. Other key issue is that of the affinity measurement: the widespread usage of non-learnable pre-defined distances, such as the Euclidean and Cosine ones. This paper proposes an efficient approach for cross-cameras data-association focused on a global solution, instead of processing cameras by pairs. To avoid the usage of fixed distances, we leverage the connectivity of Graph Neural Networks, previously unused in this scope, using a Message Passing Network to jointly learn features and similarity. We validate the proposal for pedestrian multi-view association, showing results over the EPFL multi-camera pedestrian dataset. Our approach considerably outperforms the literature data association techniques, without requiring to be trained in the same scenario in which it is tested. Our code is available at \url{http://www-vpu.eps.uam.es/publications/gnn_cca}.

Published
2022

7. Improved skin lesion recognition by a Self-Supervised Curricular Deep Learning approach

Author

Sirotkin, Kirill, Escudero-Viñolo, Marcos, Carballeira, Pablo, and SanMiguel, Juan Carlos

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

State-of-the-art deep learning approaches for skin lesion recognition often require pretraining on larger and more varied datasets, to overcome the generalization limitations derived from the reduced size of the skin lesion imaging datasets. ImageNet is often used as the pretraining dataset, but its transferring potential is hindered by the domain gap between the source dataset and the target dermatoscopic scenario. In this work, we introduce a novel pretraining approach that sequentially trains a series of Self-Supervised Learning pretext tasks and only requires the unlabeled skin lesion imaging data. We present a simple methodology to establish an ordering that defines a pretext task curriculum. For the multi-class skin lesion classification problem, and ISIC-2019 dataset, we provide experimental evidence showing that: i) a model pretrained by a curriculum of pretext tasks outperforms models pretrained by individual pretext tasks, and ii) a model pretrained by the optimal pretext task curriculum outperforms a model pretrained on ImageNet. We demonstrate that this performance gain is related to the fact that the curriculum of pretext tasks better focuses the attention of the final model on the skin lesion. Beyond performance improvement, this strategy allows for a large reduction in the training time with respect to ImageNet pretraining, which is especially advantageous for network architectures tailored for a specific problem., Comment: 11 pages, 8 figures, submitted to the Journal of Biomedical and Health Informatics (Special Issue on Skin Image Analysis in the Age of Deep Learning)

Published
2021

8. FVV Live: A real-time free-viewpoint video system with consumer electronics hardware

Author

Carballeira, Pablo, Carmona, Carlos, Díaz, César, Berjón, Daniel, Corregidor, Daniel, Cabrera, Julián, Morán, Francisco, Doblado, Carmen, Arnaldo, Sergio, Martín, María del Mar, and García, Narciso

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Multimedia
Abstract

FVV Live is a novel end-to-end free-viewpoint video system, designed for low cost and real-time operation, based on off-the-shelf components. The system has been designed to yield high-quality free-viewpoint video using consumer-grade cameras and hardware, which enables low deployment costs and easy installation for immersive event-broadcasting or videoconferencing. The paper describes the architecture of the system, including acquisition and encoding of multiview plus depth data in several capture servers and virtual view synthesis on an edge server. All the blocks of the system have been designed to overcome the limitations imposed by hardware and network, which impact directly on the accuracy of depth data and thus on the quality of virtual view synthesis. The design of FVV Live allows for an arbitrary number of cameras and capture servers, and the results presented in this paper correspond to an implementation with nine stereo-based depth cameras. FVV Live presents low motion-to-photon and end-to-end delays, which enables seamless free-viewpoint navigation and bilateral immersive communications. Moreover, the visual quality of FVV Live has been assessed through subjective assessment with satisfactory results, and additional comparative tests show that it is preferred over state-of-the-art DIBR alternatives.

Published
2020
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9. FVV Live: Real-Time, Low-Cost, Free Viewpoint Video

Author

Berjón, Daniel, Carballeira, Pablo, Cabrera, Julián, Carmona, Carlos, Corregidor, Daniel, Díaz, César, Morán, Francisco, and García, Narciso

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Multimedia
Abstract

FVV Live is a novel real-time, low-latency, end-to-end free viewpoint system including capture, transmission, synthesis on an edge server and visualization and control on a mobile terminal. The system has been specially designed for low-cost and real-time operation, only using off-the-shelf components.

Published
2020
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10. Semantic Driven Multi-Camera Pedestrian Detection

Author

López-Cifuentes, Alejandro, Escudero-Viñolo, Marcos, Bescós, Jesús, and Carballeira, Pablo

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In the current worldwide situation, pedestrian detection has reemerged as a pivotal tool for intelligent video-based systems aiming to solve tasks such as pedestrian tracking, social distancing monitoring or pedestrian mass counting. Pedestrian detection methods, even the top performing ones, are highly sensitive to occlusions among pedestrians, which dramatically degrades their performance in crowded scenarios. The generalization of multi-camera set-ups permits to better confront occlusions by combining information from different viewpoints. In this paper, we present a multi-camera approach to globally combine pedestrian detections leveraging automatically extracted scene context. Contrarily to the majority of the methods of the state-of-the-art, the proposed approach is scene-agnostic, not requiring a tailored adaptation to the target scenario\textemdash e.g., via fine-tunning. This noteworthy attribute does not require \textit{ad hoc} training with labelled data, expediting the deployment of the proposed method in real-world situations. Context information, obtained via semantic segmentation, is used 1) to automatically generate a common Area of Interest for the scene and all the cameras, avoiding the usual need of manually defining it; and 2) to obtain detections for each camera by solving a global optimization problem that maximizes coherence of detections both in each 2D image and in the 3D scene. This process yields tightly-fitted bounding boxes that circumvent occlusions or miss-detections. Experimental results on five publicly available datasets show that the proposed approach outperforms state-of-the-art multi-camera pedestrian detectors, even some specifically trained on the target scenario, signifying the versatility and robustness of the proposed method without requiring ad-hoc annotations nor human-guided configuration., Comment: Preprint accepted in Springer Knowledge and Information Systems (KAIS)

Published
2018

14. 3D reconstruction with uncalibrated cameras using the six-line conic variety

Author

Carballeira, Pablo, Ronda Prieto, José Ignacio, Valdés Morales, Antonio, Carballeira, Pablo, Ronda Prieto, José Ignacio, and Valdés Morales, Antonio

Abstract

15th IEEE International Conference on Image Processing (ICIP 2008), OCT 12-15, 2008, San Diego, CA, We present new algorithms for the recovery of the Euclidean structure from a projective calibration of a set of cameras with square pixels but otherwise arbitrarily varying intrinsic and extrinsic parameters. Our results, based on a novel geometric approach, include a closed-form solution for the case of three cameras and two known vanishing points and an efficient one-dimensional search algorithm for the case of four cameras and one known vanishing point. In addition, an algorithm for a reliable automatic detection of vanishing points on the images is presented. These techniques fit in a 3D reconstruction scheme oriented to urban scenes reconstruction. The satisfactory performance of the techniques is demonstrated with tests on synthetic and real data., Depto. de Álgebra, Geometría y Topología, Fac. de Ciencias Matemáticas, TRUE, pub

Published
2023

23. FVV Live: Real-Time, Low-Cost, Free Viewpoint Video

Author

Berjon, Daniel, primary, Carballeira, Pablo, additional, Cabrera, Julian, additional, Carmona, Carlos, additional, Corregidor, Daniel, additional, Diaz, Cesar, additional, Moran, Francisco, additional, and Garcia, Narciso, additional

Published
2020
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30. New visual coding exploration in MPEG: Super-multiview and free navigation in free viewpoint TV

Author

Lafruit, Gauthier, Munteanu, Adrian, Ceulemans, Beerend, Carballeira, Pablo, García, Sergio, Tanimoto, Masayuki, Domański, Marek, Wegner, Krzysztof, Grajek, Tomasz, Senoh, Takanori, Jung, Joël, Kovács, Péter Tamás, Goorts, Patrik, Jorissen, Lode, Lafruit, Gauthier, Munteanu, Adrian, Ceulemans, Beerend, Carballeira, Pablo, García, Sergio, Tanimoto, Masayuki, Domański, Marek, Wegner, Krzysztof, Grajek, Tomasz, Senoh, Takanori, Jung, Joël, Kovács, Péter Tamás, Goorts, Patrik, and Jorissen, Lode

Abstract

ISO/IEC MPEG and ITU-T VCEG have recently jointly issued a new multiview video compression standard, called 3D-HEVC, which reaches unpreceded compression performances for linear, dense camera arrangements. In view of supporting future high-quality, auto-stereoscopic 3D displays and Free Navigation virtual/augmented reality applications with sparse, arbitrarily arranged camera setups, innovative depth estimation and virtual view synthesis techniques with global optimizations over all camera views should be developed. Preliminary studies in response to the MPEG-FTV (Free viewpoint TV) Call for Evidence suggest these targets are within reach, with at least 6% bitrate gains over 3D-HEVC technology., SCOPUS: cp.p, SCOPUS: cp.p, info:eu-repo/semantics/published

Published
2016

32. New visual coding exploration in MPEG: Super-MultiView and Free Navigation in Free viewpoint TV

Author

Lafruit, Gauthier, primary, Domański, Marek, additional, Wegner, Krzysztof, additional, Grajek, Tomasz, additional, Senoh, Takanori, additional, Jung, Joël, additional, Kovács, Péter Tamás, additional, Goorts, Patrik, additional, Jorissen, Lode, additional, Munteanu, Adrian, additional, Ceulemans, Beerend, additional, Carballeira, Pablo, additional, García, Sergio, additional, and Tanimoto, Masayuki, additional

Published
2016
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37. Mechanische und elektrische Eigenschaften von Kohlenstoffnanofaser–keramische Nanopartikel–Polymer Verbundwerkstoffen

Author

Carballeira, Pablo

Subjects
Elektrisch, nanoparticle, Mechanisch, Nanopartikel, Nanofaser, ddc:620, Epoxydharz, Mechanical, electrical, nanofiber, epoxy
Abstract

The present research is focused on the manufacturing and analysis of composites consisting of a thermosetting polymer reinforced with fillers of nanometric dimensions. The materials were chosen to be an epoxy resin matrix and two different kinds of fillers: electrically conductive carbon nanofibers (CNFs) and ceramic titanium dioxide (TiO2) and aluminium dioxide (Al2O3) nanoparticles. In an initial step of the work, in order to understand the effect that each kind of filler had when added separately to the polymer matrix, CNF–EP and ceramic nanoparticle–EP composites were manufactured and tested. Each type of filler was dispersed in the polymer matrix using two different dispersion technologies. CNFs were dispersed in the resin with the aid of a three roll calender (TRC) whereas a torus bead mill (TML) was used in the ceramic nanoparticle case. Calendering proved to be an efficient method to disperse the untreated CNFs in the polymer matrix. The study of the physical properties of undispersed CNF composites showed that the tensile strength and the maximum sustained strain, were more sensitive to the state of dispersion of the nanofibers than the elastic modulus, fracture toughness, impact energy and electrical conductivity (for filler loadings above the percolation threshold of the system). Rheological investigation of the uncured CNF–epoxy mixture at different stages of dispersion indicated the formation of an interconnected nanofiber network within the matrix after the initial steps of calendering. CNF–EP composites showed better mechanical performance than the unmodified polymer matrix. However, the tensile modulus and strength of the CNF composites accused the presence of remaining nanofiber clusters and did not reach theoretically predicted values. Fracture toughness and resistance against impact did not seem to be so sensitive to the state of nanofiber dispersion and improved consistently with the incorporation of the CNFs. The electrical conductivity of the CNF composites saw an eight orders of magnitude percolative enhancement with increasing nanofiber content. The percolation threshold for the achieved level of CNF dispersion was found to be 0.14 vol. %. It was also determined that, for these composites, the main mechanism of electrical transmission was the electron tunnelling mechanism. Ceramic nanoparticle–EP composites were manufactured using TiO2 and Al2O3 particles as fillers in the epoxy matrix. Mechanical dispersion of the nanoparticles in the liquid polymer by means of a torus bead mill dissolver led to homogeneous distributions of particles in the matrix. Remaining particle agglomerates had a mean value of 80 nm. However, micrometer sized agglomerates could clearly be observed in the microscopical analysis of the composites, especially in the TiO2 case. The inclusion of the nanoparticles in the epoxy resin resulted in a general improvement of the modulus, strength, maximum sustained strain, fracture toughness and impact energy of the polymer matrix. Nanoparticles were able to overcome the stiffness/toughness problem. On the other hand, nanoparticle–EP composites showed lower electrical conductivity than the neat epoxy. In general, there were no significant differences between the incorporation of TiO2 or Al2O3 particles. Based on the previous results, CNFs and nanoparticles were combined as fillers to create a nanocomposite that could benefit from the electrical properties provided by the conductive CNFs and, at the same time, have improved mechanical performance thanks to the presence of the well dispersed ceramic nanoparticles. Nanoparticles and CNFs were dispersed separately to create two batches which were blended together in a dissolver mixer. This method proved effective to create well dispersed CNF–nanoparticle–epoxy composites which showed improved electrical and mechanical properties compared with the neat polymer matrix. The well dispersed ceramic nanofillers were able to introduce additional energy dissipating mechanisms in the CNF–EP composites that resulted in an improvement of their mechanical performance. With high volume loadings of nanoparticles most of the reinforcement came from the presence of the nanoparticles in the polymer matrix. Therefore, the observed trends were, in essence, similar to the ones observed in the ceramic nanoparticle–EP composites. The enhancement in the mechanical performance of the CNF composites with the inclusion of ceramic nanoparticles came at the price of an increase in the percolation threshold and a reduction of the electrical conductivity of the CNF–nanoparticle–EP composites compared with the CNF–EP materials. A modified Weber and Kamal’s fiber contact model (FCM) was used to explain the electrical behaviour of the CNF–nanoparticle–EP composites once percolation was achieved. This model was able to fit rather accurately the experimentally measured conductivity of these composites. Die vorliegende Forschungsarbeit konzentrierte sich auf die Herstellung und Analyse von Verbundwerkstoffen, die aus einem duroplastischen Polymer bestehen, das mit nanoskaligen Füllstoffen verstärkt wurde. Als Materialien wurden eine Epoxidharz-(EP) Matrix und zwei verschiedene Arten von Verstärkungsstoffen gewählt: elektrisch leitende Kohlenstoffnanofasern (CNFs) und keramische Titandioxid- (TiO2) und Aluminiumdioxid- (Al2O3) Nanopartikel. In einem ersten Schritt der Arbeit wurden CNF-EP- und TiO2-EP- bzw. Al2O3-EP-Verbundwerkstoffe gefertigt und geprüft, um die Wirkung jedes Füllstoffes alleine auf die Polymermatrix zu verstehen. Zur Dispergierung der Verstärkungsstoffe im polymeren Grundmaterial wurden zwei verschiedene Dispergiermethoden verwendet. Die Kohlenstoffnanofasern wurden mithilfe eines Dreiwalzwerks im Harz dispergiert, wohingegen für die keramischen Nanopartikel eine Tauchmühle verwendet wurde. Es stellte sich heraus, dass der Einsatz des Dreiwalz-Kalanderwerks eine effiziente Methode zur Dispergierung der unbehandelten CNFs in der Polymermatrix ist. Die Studie der physikalischen Eigenschaften von undispergierten CNF- Verbundwerkstoffen zeigte, dass die Zugfestigkeit und die maximale Dehnung deutlich stärker vom Dispergierzustand der Nanofasern abhängen als der elastische Modul, die Bruchzähigkeit, die Schlagzähigkeit und die elektrische Leitfähigkeit (für Füllstoffgehalte oberhalb der Perkolationsschwelle des Systems). Rheologische Untersuchungen von unvernetzten Kohlenstoffnanofaser-Epoxidharz-Mischungen in verschiedenen Dispergierzuständen zeigten die Bildung eines ineinandergreifenden Nanofaser-Netzes innerhalb der Matrix nach den ersten Kalanderschritten. CNF-EP-Verbundwerkstoffe zeigten bessere mechanische Eigenschaften als die unmodifizierte Polymermatrix. Der Zugelastizitätsmodul und die Zugfestigkeit dieser Werkstoffe erreichten jedoch die theoretisch vorausgesagten Werte aufgrund der im Material verbliebenen Nanofaser-Cluster nicht. Die Bruchzähigkeit und Schlagzähigkeit hingegen schienen stark durch den Dispergierzustand beeinflusst zu werden und stiegen durchweg mit steigendem Kohlenstoffnanofaser-Gehalt an. Das elektrische Leitvermögen der Nanofaser-Verbundwerkstoffe erfuhr eine perkolative Erhöhung um acht Größenordnungen mit steigendem Nanofaser-Gehalt. Die Perkolationsschwelle für das erreichte Dispergierniveau der CNFs lag bei 0,14 Vol.-%. Es wurde außerdem festgestellt, dass für diese Verbundwerkstoffe der Hauptmechanismus der elektrischen Leitfähigkeit der Tunneleffekt war. Zur Herstellung von Keramik-Nanopartikel-EP-Verbundwerkstoffen wurden TiO2- und Al2O3-Nanopartikel als Füllstoffe für eine Epoxidharzmatrix verwendet. Die mechanische Dispergierung der Nanopartikel im flüssigen Polymer mittels einer Tauchmühle führte zu einer homogenen Verteilung der Partikel in der Matrix. Die verbleibenden Partikelagglomerate hatten einen Mittelwert von 80 nm. Jedoch konnten bei der mikroskopischen Analyse der Verbundwerkstoffe besonders im Fall des TiO2 Agglomerate im Mikrometerbereich beobachtet werden. Die Verstärkung des Epoxidharzes durch die keramischen Nanopartikel führte zu einer allgemeinen Verbesserung des Moduls, der Festigkeit, der maximalen Dehnung, der Bruchzähigkeit und der Schlagzähigkeit der Polymermatrix. Die Nanopartikel konnten das Steifigkeits-/Zähigkeits-Problem überwinden. Auf der anderen Seite zeigten die Nanopartikel-EP-Werkstoffe eine geringere elektrische Leitfähigkeit als das reine Epoxidharz. Im Allgemeinen führte die Einarbeitung von TiO2 oder Al2O3 zu keinen größeren Unterschieden zwischen den beiden Werkstoffen. Beruhend auf den vorherigen Ergebnissen wurden Kohlenstoffnanofasern und Nanopartikel als Füllstoffe kombiniert, um einen Nanoverbundwerkstoff zu schaffen, der sowohl bessere elektrische Eigenschaften, die durch die leitenden Nanofasern hervorgerufen wurden, zeigt als auch eine gute mechanische Leistungsfähigkeit dank der Verstärkung durch die gut dispergierten Nanopartikel. Die keramischen Nanopartikel und die Nanofasern wurden getrennt dispergiert und so zwei Mischungen hergestellt, die dann in einem Dissolver zusammengemischt wurden. Diese Methode erwies sich als wirksam, um gut dispergierte CNF-Nanopartikel-Epoxy-Verbundwerkstoffe zu fertigen, die verbesserte elektrische und mechanische Eigenschaften im Vergleich zur ungefüllten Polymermatrix zeigten. Die gut dispergierten nanoskaligen Füllstoffe waren im Stande zusätzliche Energiedissipations-Mechanismen im CNF-EP-Verbundwerkstoff zu induzieren, die eine allgemeine Verbesserung der mechanischen Eigenschaften zur Folge hatten. Bei den Werkstoffen mit einem hohen Nanopartikelvolumengehalt wurde die Verstärkungswirkung vor allem durch die Nanopartikel hervorgerufen, und die hier beobachteten Tendenzen sind ähnlich wie die der reinen Keramik-Nanopartikel-EP-Materialien. Die Erhöhung der mechanischen Eigenschaften der CNF-Verbundwerkstoffe durch die keramischen Nanopartikeln ging auf Kosten der elektrischen Eigenschaften. Ein Anstieg der Perkolationsschwelle und eine Reduktion der elektrischen Leitfähigkeit gegenüber dem reinen CNF-EP-Material waren die Folge. Ein modifiziertes Faser-Kontakt-Modell (FKM) von Weber und Kamal wurde verwendet, um das elektrische Verhalten der CNF-Nanopartikel-EP-Verbundwerkstoffe nach Erreichen der Perkolation zu erklären. Dieses Modell war im Stande die experimentell gemessene Leitfähigkeit der Verbundwerkstoffe relativ genau zu beschreiben.

Published
2010

38. Mechanical and electrical properties of carbon nanofiber–ceramic nanoparticle–polymer composites

Author

Carballeira, Pablo

Subjects
Elektrisch, nanoparticle, Mechanisch, Nanopartikel, Nanofaser, ddc:620, Epoxydharz, Mechanical, electrical, nanofiber, epoxy
Abstract

The present research is focused on the manufacturing and analysis of composites consisting of a thermosetting polymer reinforced with fillers of nanometric dimensions. The materials were chosen to be an epoxy resin matrix and two different kinds of fillers: electrically conductive carbon nanofibers (CNFs) and ceramic titanium dioxide (TiO2) and aluminium dioxide (Al2O3) nanoparticles. In an initial step of the work, in order to understand the effect that each kind of filler had when added separately to the polymer matrix, CNF–EP and ceramic nanoparticle–EP composites were manufactured and tested. Each type of filler was dispersed in the polymer matrix using two different dispersion technologies. CNFs were dispersed in the resin with the aid of a three roll calender (TRC) whereas a torus bead mill (TML) was used in the ceramic nanoparticle case. Calendering proved to be an efficient method to disperse the untreated CNFs in the polymer matrix. The study of the physical properties of undispersed CNF composites showed that the tensile strength and the maximum sustained strain, were more sensitive to the state of dispersion of the nanofibers than the elastic modulus, fracture toughness, impact energy and electrical conductivity (for filler loadings above the percolation threshold of the system). Rheological investigation of the uncured CNF–epoxy mixture at different stages of dispersion indicated the formation of an interconnected nanofiber network within the matrix after the initial steps of calendering. CNF–EP composites showed better mechanical performance than the unmodified polymer matrix. However, the tensile modulus and strength of the CNF composites accused the presence of remaining nanofiber clusters and did not reach theoretically predicted values. Fracture toughness and resistance against impact did not seem to be so sensitive to the state of nanofiber dispersion and improved consistently with the incorporation of the CNFs. The electrical conductivity of the CNF composites saw an eight orders of magnitude percolative enhancement with increasing nanofiber content. The percolation threshold for the achieved level of CNF dispersion was found to be 0.14 vol. %. It was also determined that, for these composites, the main mechanism of electrical transmission was the electron tunnelling mechanism. Ceramic nanoparticle–EP composites were manufactured using TiO2 and Al2O3 particles as fillers in the epoxy matrix. Mechanical dispersion of the nanoparticles in the liquid polymer by means of a torus bead mill dissolver led to homogeneous distributions of particles in the matrix. Remaining particle agglomerates had a mean value of 80 nm. However, micrometer sized agglomerates could clearly be observed in the microscopical analysis of the composites, especially in the TiO2 case. The inclusion of the nanoparticles in the epoxy resin resulted in a general improvement of the modulus, strength, maximum sustained strain, fracture toughness and impact energy of the polymer matrix. Nanoparticles were able to overcome the stiffness/toughness problem. On the other hand, nanoparticle–EP composites showed lower electrical conductivity than the neat epoxy. In general, there were no significant differences between the incorporation of TiO2 or Al2O3 particles. Based on the previous results, CNFs and nanoparticles were combined as fillers to create a nanocomposite that could benefit from the electrical properties provided by the conductive CNFs and, at the same time, have improved mechanical performance thanks to the presence of the well dispersed ceramic nanoparticles. Nanoparticles and CNFs were dispersed separately to create two batches which were blended together in a dissolver mixer. This method proved effective to create well dispersed CNF–nanoparticle–epoxy composites which showed improved electrical and mechanical properties compared with the neat polymer matrix. The well dispersed ceramic nanofillers were able to introduce additional energy dissipating mechanisms in the CNF–EP composites that resulted in an improvement of their mechanical performance. With high volume loadings of nanoparticles most of the reinforcement came from the presence of the nanoparticles in the polymer matrix. Therefore, the observed trends were, in essence, similar to the ones observed in the ceramic nanoparticle–EP composites. The enhancement in the mechanical performance of the CNF composites with the inclusion of ceramic nanoparticles came at the price of an increase in the percolation threshold and a reduction of the electrical conductivity of the CNF–nanoparticle–EP composites compared with the CNF–EP materials. A modified Weber and Kamal’s fiber contact model (FCM) was used to explain the electrical behaviour of the CNF–nanoparticle–EP composites once percolation was achieved. This model was able to fit rather accurately the experimentally measured conductivity of these composites. Die vorliegende Forschungsarbeit konzentrierte sich auf die Herstellung und Analyse von Verbundwerkstoffen, die aus einem duroplastischen Polymer bestehen, das mit nanoskaligen Füllstoffen verstärkt wurde. Als Materialien wurden eine Epoxidharz-(EP) Matrix und zwei verschiedene Arten von Verstärkungsstoffen gewählt: elektrisch leitende Kohlenstoffnanofasern (CNFs) und keramische Titandioxid- (TiO2) und Aluminiumdioxid- (Al2O3) Nanopartikel. In einem ersten Schritt der Arbeit wurden CNF-EP- und TiO2-EP- bzw. Al2O3-EP-Verbundwerkstoffe gefertigt und geprüft, um die Wirkung jedes Füllstoffes alleine auf die Polymermatrix zu verstehen. Zur Dispergierung der Verstärkungsstoffe im polymeren Grundmaterial wurden zwei verschiedene Dispergiermethoden verwendet. Die Kohlenstoffnanofasern wurden mithilfe eines Dreiwalzwerks im Harz dispergiert, wohingegen für die keramischen Nanopartikel eine Tauchmühle verwendet wurde. Es stellte sich heraus, dass der Einsatz des Dreiwalz-Kalanderwerks eine effiziente Methode zur Dispergierung der unbehandelten CNFs in der Polymermatrix ist. Die Studie der physikalischen Eigenschaften von undispergierten CNF- Verbundwerkstoffen zeigte, dass die Zugfestigkeit und die maximale Dehnung deutlich stärker vom Dispergierzustand der Nanofasern abhängen als der elastische Modul, die Bruchzähigkeit, die Schlagzähigkeit und die elektrische Leitfähigkeit (für Füllstoffgehalte oberhalb der Perkolationsschwelle des Systems). Rheologische Untersuchungen von unvernetzten Kohlenstoffnanofaser-Epoxidharz-Mischungen in verschiedenen Dispergierzuständen zeigten die Bildung eines ineinandergreifenden Nanofaser-Netzes innerhalb der Matrix nach den ersten Kalanderschritten. CNF-EP-Verbundwerkstoffe zeigten bessere mechanische Eigenschaften als die unmodifizierte Polymermatrix. Der Zugelastizitätsmodul und die Zugfestigkeit dieser Werkstoffe erreichten jedoch die theoretisch vorausgesagten Werte aufgrund der im Material verbliebenen Nanofaser-Cluster nicht. Die Bruchzähigkeit und Schlagzähigkeit hingegen schienen stark durch den Dispergierzustand beeinflusst zu werden und stiegen durchweg mit steigendem Kohlenstoffnanofaser-Gehalt an. Das elektrische Leitvermögen der Nanofaser-Verbundwerkstoffe erfuhr eine perkolative Erhöhung um acht Größenordnungen mit steigendem Nanofaser-Gehalt. Die Perkolationsschwelle für das erreichte Dispergierniveau der CNFs lag bei 0,14 Vol.-%. Es wurde außerdem festgestellt, dass für diese Verbundwerkstoffe der Hauptmechanismus der elektrischen Leitfähigkeit der Tunneleffekt war. Zur Herstellung von Keramik-Nanopartikel-EP-Verbundwerkstoffen wurden TiO2- und Al2O3-Nanopartikel als Füllstoffe für eine Epoxidharzmatrix verwendet. Die mechanische Dispergierung der Nanopartikel im flüssigen Polymer mittels einer Tauchmühle führte zu einer homogenen Verteilung der Partikel in der Matrix. Die verbleibenden Partikelagglomerate hatten einen Mittelwert von 80 nm. Jedoch konnten bei der mikroskopischen Analyse der Verbundwerkstoffe besonders im Fall des TiO2 Agglomerate im Mikrometerbereich beobachtet werden. Die Verstärkung des Epoxidharzes durch die keramischen Nanopartikel führte zu einer allgemeinen Verbesserung des Moduls, der Festigkeit, der maximalen Dehnung, der Bruchzähigkeit und der Schlagzähigkeit der Polymermatrix. Die Nanopartikel konnten das Steifigkeits-/Zähigkeits-Problem überwinden. Auf der anderen Seite zeigten die Nanopartikel-EP-Werkstoffe eine geringere elektrische Leitfähigkeit als das reine Epoxidharz. Im Allgemeinen führte die Einarbeitung von TiO2 oder Al2O3 zu keinen größeren Unterschieden zwischen den beiden Werkstoffen. Beruhend auf den vorherigen Ergebnissen wurden Kohlenstoffnanofasern und Nanopartikel als Füllstoffe kombiniert, um einen Nanoverbundwerkstoff zu schaffen, der sowohl bessere elektrische Eigenschaften, die durch die leitenden Nanofasern hervorgerufen wurden, zeigt als auch eine gute mechanische Leistungsfähigkeit dank der Verstärkung durch die gut dispergierten Nanopartikel. Die keramischen Nanopartikel und die Nanofasern wurden getrennt dispergiert und so zwei Mischungen hergestellt, die dann in einem Dissolver zusammengemischt wurden. Diese Methode erwies sich als wirksam, um gut dispergierte CNF-Nanopartikel-Epoxy-Verbundwerkstoffe zu fertigen, die verbesserte elektrische und mechanische Eigenschaften im Vergleich zur ungefüllten Polymermatrix zeigten. Die gut dispergierten nanoskaligen Füllstoffe waren im Stande zusätzliche Energiedissipations-Mechanismen im CNF-EP-Verbundwerkstoff zu induzieren, die eine allgemeine Verbesserung der mechanischen Eigenschaften zur Folge hatten. Bei den Werkstoffen mit einem hohen Nanopartikelvolumengehalt wurde die Verstärkungswirkung vor allem durch die Nanopartikel hervorgerufen, und die hier beobachteten Tendenzen sind ähnlich wie die der reinen Keramik-Nanopartikel-EP-Materialien. Die Erhöhung der mechanischen Eigenschaften der CNF-Verbundwerkstoffe durch die keramischen Nanopartikeln ging auf Kosten der elektrischen Eigenschaften. Ein Anstieg der Perkolationsschwelle und eine Reduktion der elektrischen Leitfähigkeit gegenüber dem reinen CNF-EP-Material waren die Folge. Ein modifiziertes Faser-Kontakt-Modell (FKM) von Weber und Kamal wurde verwendet, um das elektrische Verhalten der CNF-Nanopartikel-EP-Verbundwerkstoffe nach Erreichen der Perkolation zu erklären. Dieses Modell war im Stande die experimentell gemessene Leitfähigkeit der Verbundwerkstoffe relativ genau zu beschreiben.

Published
2010

41. Latency Analysis for a Multi-Processor Multiview Video Encoder Implementation

Author

Carballeira, Pablo, Cabrera, Julián, Ortega, Antonio, Jaureguizar, Fernando, García, Narciso, Carballeira, Pablo, Cabrera, Julián, Ortega, Antonio, Jaureguizar, Fernando, and García, Narciso

Abstract

In this paper we extend a previous encoding latency analysis framework for arbitrary multiview video coding prediction structures with a new multi-processor multiview encoder model. As opposed to the fixed scheme where each processor is in charge of encoding a single view, this new model focuses on a flexible assignment of the encoding of frames among the pool of available processors. This new model is more suitable for realistic scenarios in which the number of views and processors is different. Moreover, we show that for this new encoder model, a more efficient use of the processors can be achieved by means of appropriate frame coding ordering algorithms. This is especially interesting in real-time encoding applications in which frame processing time constraints are imposed in order to maintain low encoding latency. Finally, we evaluate the latency performance of this new encoder model and show its advantages over the fixed encoder scheme., APSIPA ASC 2009: Asia-Pacific Signal and Information Processing Association, 2009 Annual Summit and Conference. 4-7 October 2009. Sapporo, Japan. Oral session: Multiview/3D Video Processing I (6 October 2009).

Published
2009

49. Mechanical and electrical properties of carbon nanofiber–ceramic nanoparticle–polymer composites

Author

Carballeira, Pablo and Carballeira, Pablo

Abstract

The present research is focused on the manufacturing and analysis of composites consisting of a thermosetting polymer reinforced with fillers of nanometric dimensions. The materials were chosen to be an epoxy resin matrix and two different kinds of fillers: electrically conductive carbon nanofibers (CNFs) and ceramic titanium dioxide (TiO2) and aluminium dioxide (Al2O3) nanoparticles. In an initial step of the work, in order to understand the effect that each kind of filler had when added separately to the polymer matrix, CNF–EP and ceramic nanoparticle–EP composites were manufactured and tested. Each type of filler was dispersed in the polymer matrix using two different dispersion technologies. CNFs were dispersed in the resin with the aid of a three roll calender (TRC) whereas a torus bead mill (TML) was used in the ceramic nanoparticle case. Calendering proved to be an efficient method to disperse the untreated CNFs in the polymer matrix. The study of the physical properties of undispersed CNF composites showed that the tensile strength and the maximum sustained strain, were more sensitive to the state of dispersion of the nanofibers than the elastic modulus, fracture toughness, impact energy and electrical conductivity (for filler loadings above the percolation threshold of the system). Rheological investigation of the uncured CNF–epoxy mixture at different stages of dispersion indicated the formation of an interconnected nanofiber network within the matrix after the initial steps of calendering. CNF–EP composites showed better mechanical performance than the unmodified polymer matrix. However, the tensile modulus and strength of the CNF composites accused the presence of remaining nanofiber clusters and did not reach theoretically predicted values. Fracture toughness and resistance against impact did not seem to be so sensitive to the state of nanofiber dispersion and improved consistently with the incorporation of the CNFs. The electrical conductivity of the C, Die vorliegende Forschungsarbeit konzentrierte sich auf die Herstellung und Analyse von Verbundwerkstoffen, die aus einem duroplastischen Polymer bestehen, das mit nanoskaligen Füllstoffen verstärkt wurde. Als Materialien wurden eine Epoxidharz-(EP) Matrix und zwei verschiedene Arten von Verstärkungsstoffen gewählt: elektrisch leitende Kohlenstoffnanofasern (CNFs) und keramische Titandioxid- (TiO2) und Aluminiumdioxid- (Al2O3) Nanopartikel. In einem ersten Schritt der Arbeit wurden CNF-EP- und TiO2-EP- bzw. Al2O3-EP-Verbundwerkstoffe gefertigt und geprüft, um die Wirkung jedes Füllstoffes alleine auf die Polymermatrix zu verstehen. Zur Dispergierung der Verstärkungsstoffe im polymeren Grundmaterial wurden zwei verschiedene Dispergiermethoden verwendet. Die Kohlenstoffnanofasern wurden mithilfe eines Dreiwalzwerks im Harz dispergiert, wohingegen für die keramischen Nanopartikel eine Tauchmühle verwendet wurde. Es stellte sich heraus, dass der Einsatz des Dreiwalz-Kalanderwerks eine effiziente Methode zur Dispergierung der unbehandelten CNFs in der Polymermatrix ist. Die Studie der physikalischen Eigenschaften von undispergierten CNF- Verbundwerkstoffen zeigte, dass die Zugfestigkeit und die maximale Dehnung deutlich stärker vom Dispergierzustand der Nanofasern abhängen als der elastische Modul, die Bruchzähigkeit, die Schlagzähigkeit und die elektrische Leitfähigkeit (für Füllstoffgehalte oberhalb der Perkolationsschwelle des Systems). Rheologische Untersuchungen von unvernetzten Kohlenstoffnanofaser-Epoxidharz-Mischungen in verschiedenen Dispergierzuständen zeigten die Bildung eines ineinandergreifenden Nanofaser-Netzes innerhalb der Matrix nach den ersten Kalanderschritten. CNF-EP-Verbundwerkstoffe zeigten bessere mechanische Eigenschaften als die unmodifizierte Polymermatrix. Der Zugelastizitätsmodul und die Zugfestigkeit dieser Werkstoffe erreichten jedoch die theoretisch vorausgesagten Werte aufgrund der im Material verbliebenen Nanofaser-Cluster nicht. Die Bruc

50. Deep learning analysis of vessel reduction images after EVAR

Author

Riera del Moral, Javier, Carballeira López, Pablo, UAM. Departamento de Tecnología Electrónica y de las Comunicaciones, and Carballeira, Pablo (Tutor)

Subjects
Endovascular aortic repair, Telecomunicaciones, Aortic aneurysm, cardiovascular system, EVAR, cardiovascular diseases
Abstract

Máster Universitario en Deep Learning for Audio and Video Signal Processing, An aortic aneurysm is an enlargement of the aorta, the largest artery supplying blood to the body. The most common aneurysms are abdominal aortic aneurysms (AAA). AAAs tend to grow and rupture, resulting in a high risk of death from internal bleeding. The most commonly used surgical treatment today is the placement of an aortic stent graft, EVAR (EndoVascular Aneurysm Repair). EVAR is a self-expanding device that is placed inside the diseased artery to exclude the aneurysm from circulation, reducing the pressure on the aneurysm and eliminating the risk of AAA rupture. The best prognostic sign of this treatment is the reduction in size of the AAA over time, once depressurization has occurred. An AAA that is correctly treated with EVAR and excluded from circulation is called an aneurysmal sac. However, EVAR is not free of complications, the most frequent are the so-called leaks, which are small inflows of blood into the treated AAA that condition the pressurization of the aneurysmal sac and therefore the reappearance of the risk of rupture and bleeding, which is always accompanied by a lack of reduction in the size of the sac. There are different types of leaks depending on where blood enters the sac. Early detection is essential to plan appropriate treatment in time. The current diagnostic test to follow up EVARs is CT (Computed Tomography). The images obtained with this technique are studied by physicians looking for contrast spots within the treated AAA that indicate the presence of leaks. These contrast peaks may be evident in some cases, but difficult to see in others, especially considering the large volume of images per CT scan. The model proposed in this study consists of a detection network, based on RetinaNet, to localize the sac in the CT images and remove the surrounding noise. Then using a binary classification model based on convolutional networks, both 2D and 3D, to analyze the images and make a prediction of the evolution of the aneurysm size, which would allow physicians to perform targeted surveillance on patients at higher risk of leaking.

Published
2021

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