Worst-case delay analysis of real-time switched Ethernet networks with flow local synchronization

Les réseaux Ethernet commuté full-duplex constituent des solutions intéressantes pour des applications industrielles. Mais le non-déterminisme d’un commutateur IEEE 802.1d, fait que l’analyse pire cas de délai de flux critiques est encore un problème ouvert. Plusieurs méthodes ont été proposées pour obtenir des bornes supérieures des délais de communication sur des réseaux Ethernet commuté full duplex temps réels, faisant l’hypothèse que le trafic en entrée du réseau peut être borné. Le problème principal reste le pessimisme introduit par la méthode de calcul de cette borne supérieure du délai. Ces méthodes considèrent que tous les flux transmis sur le réseau sont indépendants. Ce qui est vrai pour les flux émis par des nœuds sources différents car il n’existe pas, dans le cas général, d’horloge globale permettant de synchroniser les flux. Mais pour les flux émis par un même nœud source, il est possible de faire l’hypothèse d’une synchronisation locale de ces flux. Une telle hypothèse permet de bâtir un modèle plus précis des flux et en conséquence élimine des scénarios impossibles qui augmentent le pessimisme du calcul. Le sujet principal de cette thèse est d’étudier comment des flux périodiques synchronisés par des offsets peuvent être gérés dans le calcul des bornes supérieures des délais sur un réseau Ethernet commuté temps-réel. Dans un premier temps, il s’agit de présenter l’impact des contraintes d’offsets sur le calcul des bornes supérieures des délais de bout en bout. Il s’agit ensuite de présenter comment intégrer ces contraintes d’offsets dans les approches de calcul basées sur le Network Calculus et la méthode des Trajectoires. Une méthode Calcul Réseau modifiée et une méthode Trajectoires modifiée sont alors développées et les performances obtenues sont comparées. Le réseau avionique AFDX (Avionics Full-Duplex Switched Ethernet) est pris comme exemple d’un réseau Ethernet commuté full-duplex. Une configuration AFDX industrielle avec un millier de flux est présentée. Cette configuration industrielle est alors évaluée à l’aide des deux approches, selon un choix d’allocation d’offsets donné. De plus, différents algorithmes d’allocation des offsets sont testés sur cette configuration industrielle, pour trouver un algorithme d’allocation quasi-optimal. Une analyse de pessimisme des bornes supérieures calculées est alors proposée. Cette analyse est basée sur l’approche des trajectoires (rendue optimiste) qui permet de calculer une sous-approximation du délai pire-cas. La différence entre la borne supérieure du délai (calculée par une méthode donnée) et la sous-approximation du délai pire cas donne une borne supérieure du pessimisme de la méthode. Cette analyse fournit des résultats intéressants sur le pessimisme des approches Calcul Réseau et méthode des Trajectoires. La dernière partie de la thèse porte sur une architecture de réseau temps réel hétérogène obtenue par connexion de réseaux CAN via des ponts sur un réseau fédérateur de type Ethernet commuté. Deux approches, une basée sur les composants et l’autre sur les Trajectoires sont proposées pour permettre une analyse des délais pire-cas sur un tel réseau. La capacité de calcul d’une borne supérieure des délais pire-cas dans le contexte d’une architecture hétérogène est intéressante pour les domaines industriels. ABSTRACT : Full-duplex switched Ethernet is a promising candidate for interconnecting real-time industrial applications. But due to IEEE 802.1d indeterminism, the worst-case delay analysis of critical flows supported by such a network is still an open problem. Several methods have been proposed for upper-bounding communication delays on a real-time switched Ethernet network, assuming that the incoming traffic can be upper bounded. The main problem remaining is to assess the tightness, i.e. the pessimism, of the method calculating this upper bound on the communication delay. These methods consider that all flows transmitted over the network are independent. This is true for flows emitted by different source nodes since, in general, there is no global clock synchronizing them. But the flows emitted by the same source node are local synchronized. Such an assumption helps to build a more precise flow model that eliminates some impossible communication scenarios which lead to a pessimistic delay upper bounds. The core of this thesis is to study how local periodic flows synchronized with offsets can be handled when computing delay upper-bounds on a real-time switched Ethernet. In a first step, the impact of these offsets on the delay upper-bound computation is illustrated. Then, the integration of offsets in the Network Calculus and the Trajectory approaches is introduced. Therefore, a modified Network Calculus approach and a modified Trajectory approach are developed whose performances are compared on an Avionics Full-DupleX switched Ethernet (AFDX) industrial configuration with one thousand of flows. It has been shown that, in the context of this AFDX configuration, the Trajectory approach leads to slightly tighter end-to-end delay upper bounds than the ones of the Network Calculus approach. But offsets of local flows have to be chosen. Different offset assignment algorithms are then investigated on the AFDX industrial configuration. A near-optimal assignment can be exhibited. Next, a pessimism analysis of the computed upper-bounds is proposed. This analysis is based on the Trajectory approach (made optimistic) which computes an under-estimation of the worst-case delay. The difference between the upper-bound (computed by a given method) and the under-estimation of the worst-case delay gives an upper-bound of the pessimism of the method. This analysis gives interesting comparison results on the Network Calculus and the Trajectory approaches pessimism. The last part of the thesis, deals with a real-time heterogeneous network architecture where CAN buses are interconnected through a switched Ethernet backbone using dedicated bridges. Two approaches, the component-based approach and the Trajectory approach, are developed to conduct a worst-case delay analysis for such a network. Clearly, the ability to compute end-to-end delays upper-bounds in the context of heterogeneous network architecture is promising for industrial domains

Proceedings of Junior Researcher Workshop on Real-Time Computing

It is our great pleasure to welcome you to Junior Researcher Workshop on Real-Time Computing 2007, which is held conjointly with the 15th conference on Real-Time and Network Systems (RTNS'07). The first successful edition was held conjointly with the French Summer School on Real-Time Systems 2005 (http://etr05.loria.fr). Its main purpose is to bring together junior researchers (Ph.D. students, postdoc, ...) working on real-time systems. This workshop is a good opportunity to present our works and share ideas with other junior researchers and not only, since we will present our work to the audience of the main conference. In response to the call for papers, 14 papers were submitted and the international Program Committee provided detailed comments to improve these work-in-progress papers. We hope that our remarks will help the authors to submit improved long versions of theirs papers to the next edition of RTNS. JRWRTC'07 would not be possible without the generous contribution of many volunteers and institutions which supported RTNS'07. First, we would like to express our sincere gratitude to our sponsors for their financial support : Conseil Général de Meuthe et Moselle, Conseil Régional de Lorraine, Communauté Urbaine du Grand Nancy, Université Henri Poincaré, Institut National Polytechnique de Lorraine and LORIA and INRIA Lorraine. We are thankful to Pascal Mary for authorizing us to use his nice picture of “place Stanislas” for the proceedings and web site (many others are available at www.laplusbelleplacedumonde.com). Finally, we are most grateful to the local organizing committee that helped to organize the conference

Flexible management of bandwidth and redundancy in fieldbuses

Doutoramento em Engenharia ElectrotécnicaOs sistemas distribuídos embarcados (Distributed Embedded Systems – DES) têm sido usados ao longo dos últimos anos em muitos domínios de aplicação, da robótica, ao controlo de processos industriais passando pela aviónica e pelas aplicações veiculares, esperando-se que esta tendência continue nos próximos anos. A confiança no funcionamento é uma propriedade importante nestes domínios de aplicação, visto que os serviços têm de ser executados em tempo útil e de forma previsível, caso contrário, podem ocorrer danos económicos ou a vida de seres humanos poderá ser posta em causa. Na fase de projecto destes sistemas é impossível prever todos os cenários de falhas devido ao não determinismo do ambiente envolvente, sendo necessária a inclusão de mecanismos de tolerância a falhas. Adicionalmente, algumas destas aplicações requerem muita largura de banda, que também poderá ser usada para a evolução dos sistemas, adicionandolhes novas funcionalidades. A flexibilidade de um sistema é uma propriedade importante, pois permite a sua adaptação às condições e requisitos envolventes, contribuindo também para a simplicidade de manutenção e reparação. Adicionalmente, nos sistemas embarcados, a flexibilidade também é importante por potenciar uma melhor utilização dos, muitas vezes escassos, recursos existentes. Uma forma evidente de aumentar a largura de banda e a tolerância a falhas dos sistemas embarcados distribuídos é a replicação dos barramentos do sistema. Algumas soluções existentes, quer comerciais quer académicas, propõem a replicação dos barramentos para aumento da largura de banda ou para aumento da tolerância a falhas. No entanto e quase invariavelmente, o propósito é apenas um, sendo raras as soluções que disponibilizam uma maior largura de banda e um aumento da tolerância a falhas. Um destes raros exemplos é o FlexRay, com a limitação de apenas ser permitido o uso de dois barramentos. Esta tese apresentada e discute uma proposta para usar a replicação de barramentos de uma forma flexível com o objectivo duplo de aumentar a largura de banda e a tolerância a falhas. A flexibilidade dos protocolos propostos também permite a gestão dinâmica da topologia da rede, sendo o número de barramentos apenas limitado pelo hardware/software. As propostas desta tese foram validadas recorrendo ao barramento de campo CAN – Controller Area Network, escolhido devido à sua grande implantação no mercado. Mais especificamente, as soluções propostas foram implementadas e validadas usando um paradigma que combina flexibilidade com comunicações event-triggered e time-triggered: o FTT – Flexible Time- Triggered. No entanto, uma generalização para CAN nativo é também apresentada e discutida. A inclusão de mecanismos de replicação do barramento impõe a alteração dos antigos protocolos de replicação e substituição do nó mestre, bem como a definição de novos protocolos para esta finalidade. Este trabalho tira partido da arquitectura centralizada e da replicação do nó mestre para suportar de forma eficiente e flexível a replicação de barramentos. Em caso de ocorrência de uma falta num barramento (ou barramentos) que poderia provocar uma falha no sistema, os protocolos e componentes propostos nesta tese fazem com que o sistema reaja, mudando para um modo de funcionamento degradado. As mensagens que estavam a ser transmitidas nos barramentos onde ocorreu a falta são reencaminhadas para os outros barramentos. A replicação do nó mestre baseia-se numa estratégia líder-seguidores (leaderfollowers), onde o líder (leader) controla todo o sistema enquanto os seguidores (followers) servem como nós de reserva. Se um erro ocorrer no nó líder, um dos nós seguidores passará a controlar o sistema de uma forma transparente e mantendo as mesmas funcionalidades. As propostas desta tese foram também generalizadas para CAN nativo, tendo sido para tal propostos dois componentes adicionais. É, desta forma possível ter as mesmas capacidades de tolerância a falhas ao nível dos barramentos juntamente com a gestão dinâmica da topologia de rede. Todas as propostas desta tese foram implementadas e avaliadas. Uma implementação inicial, apenas com um barramento foi avaliada recorrendo a uma aplicação real, uma equipa de futebol robótico onde o protocolo FTT-CAN foi usado no controlo de movimento e da odometria. A avaliação do sistema com múltiplos barramentos foi feita numa plataforma de teste em laboratório. Para tal foi desenvolvido um sistema de injecção de faltas que permite impor faltas nos barramentos e nos nós mestre, e um sistema de medida de atrasos destinado a medir o tempo de resposta após a ocorrência de uma falta.Distributed embedded systems (DES) have been widely used in the last few decades in several application domains, from robotics, industrial process control, avionics and automotive. In fact, it is expectable that this trend will continue in the next years. In some of these application fields the dependability requirements are very important since the fail to provide services in a timely and predictable manner may cause important economic losses or even put humans in risk. In the design phase it is impossible to predict all the possible scenarios of faults, due to the non deterministic behaviour of the surrounding environment. In that way, the fault tolerance mechanisms must be included in the distributed embedded system to prevent failures occurrence. Also, many application domains require a high available bandwidth to perform the desired functions, or to turn possible the scaling with the addition of new features. The flexibility of a system also plays an important role, since it improves the capability to adapt to the surrounding world, and to the simplicity of the repair and maintenance. The flexibility improves the efficiency of all the system by providing a way to efficiently manage the available resources. This is very important in embedded systems due to the limited resources often available. A natural way to improve the bandwidth and the fault tolerance in distributed systems is to use replicated buses. Commercial and academic solutions propose the use of replicated fieldbuses for a single purpose only, either to improve the fault tolerance or to improve the available bandwidth, being the first the most common. One illustrative exception is FlexRay where the bus replica can be used to improve the bandwidth of the overall system, besides enabling redundant communications. However, only one bus replica can be used. In this thesis, a flexible bus replication scheme to improve both the dependability and the throughput of fieldbuses is presented and studied. It can be applied to any number of replicated buses, provided the required hardware support is available. The flexible use of the replicated buses can achieve an also flexible management of the network topology. This claim has been validated using the Controller Area Network (CAN) fieldbus, which has been chosen because it is widely spread in millions of systems. In fact, the proposed solution uses a paradigm that combines flexibility, time and event triggered communication, that is the Flexible Time- Triggered over CAN network (FTT-CAN). However, a generalization to native CAN is also presented and studied. The inclusion of bus replication in FTT-CAN imposes not only new mechanisms but also changes of the mechanisms associated with the master replication, which has been already studied in previous research work. In this work, these mechanisms were combined and take advantage of the centralized architecture and of the redundant masters to support an efficient and flexible bus replication. When considering the system operation, if a fault in the bus (or buses) occurs, and the consequent error leads to a system failure, the system reacts, switching to a degraded mode, where the message flows that were transmitted in the faulty bus (or buses) change to the non-faulty ones. The central node replication uses a leader-follower strategy, where the leader controls the system while the followers serve as backups. If an error occurs in the leader, a backup will take the system control maintaining the system with the same functionalities. The system has been generalized for native CAN, using two additional components that provide the same fault tolerance capabilities at the bus level, and also enable the dynamic management of the network topology. All the referred proposals were implemented and assessed in the scope of this work. The single bus version of FTT-CAN was assessed using a real application, a robotic soccer team, which has obtained excellent results in international competitions. There, the FTT-CAN based embedded system has been applied in the low level control, where, mainly it is responsible for the motion control and odometry. For the case of the multiple buses system, the assessment was performed in a laboratory test bed. For this, a fault injector was developed in order to impose faults in the buses and in the central nodes. To measure the time reaction of the system, a special hardware has been developed: a delay measurement system. It is able to measure delays between two important time marks for posterior offline analysis of the obtained values

Real-Time Sensor Networks and Systems for the Industrial IoT

The Industrial Internet of Things (Industrial IoT—IIoT) has emerged as the core construct behind the various cyber-physical systems constituting a principal dimension of the fourth Industrial Revolution. While initially born as the concept behind specific industrial applications of generic IoT technologies, for the optimization of operational efficiency in automation and control, it quickly enabled the achievement of the total convergence of Operational (OT) and Information Technologies (IT). The IIoT has now surpassed the traditional borders of automation and control functions in the process and manufacturing industry, shifting towards a wider domain of functions and industries, embraced under the dominant global initiatives and architectural frameworks of Industry 4.0 (or Industrie 4.0) in Germany, Industrial Internet in the US, Society 5.0 in Japan, and Made-in-China 2025 in China. As real-time embedded systems are quickly achieving ubiquity in everyday life and in industrial environments, and many processes already depend on real-time cyber-physical systems and embedded sensors, the integration of IoT with cognitive computing and real-time data exchange is essential for real-time analytics and realization of digital twins in smart environments and services under the various frameworks’ provisions. In this context, real-time sensor networks and systems for the Industrial IoT encompass multiple technologies and raise significant design, optimization, integration and exploitation challenges. The ten articles in this Special Issue describe advances in real-time sensor networks and systems that are significant enablers of the Industrial IoT paradigm. In the relevant landscape, the domain of wireless networking technologies is centrally positioned, as expected

Towards Scalable Design of Future Wireless Networks

Wireless operators face an ever-growing challenge to meet the throughput and processing requirements of billions of devices that are getting connected. In current wireless networks, such as LTE and WiFi, these requirements are addressed by provisioning more resources: spectrum, transmitters, and baseband processors. However, this simple add-on approach to scale system performance is expensive and often results in resource underutilization. What are, then, the ways to efficiently scale the throughput and operational efficiency of these wireless networks? To answer this question, this thesis explores several potential designs: utilizing unlicensed spectrum to augment the bandwidth of a licensed network; coordinating transmitters to increase system throughput; and finally, centralizing wireless processing to reduce computing costs. First, we propose a solution that allows LTE, a licensed wireless standard, to co-exist with WiFi in the unlicensed spectrum. The proposed solution bridges the incompatibility between the fixed access of LTE, and the random access of WiFi, through channel reservation. It achieves a fair LTE-WiFi co-existence despite the transmission gaps and unequal frame durations. Second, we consider a system where different MIMO transmitters coordinate to transmit data of multiple users. We present an adaptive design of the channel feedback protocol that mitigates interference resulting from the imperfect channel information. Finally, we consider a Cloud-RAN architecture where a datacenter or a cloud resource processes wireless frames. We introduce a tree-based design for real-time transport of baseband samples and provide its end-to-end schedulability and capacity analysis. We also present a processing framework that combines real-time scheduling with fine-grained parallelism. The framework reduces processing times by migrating parallelizable tasks to idle compute resources, and thus, decreases the processing deadline-misses at no additional cost. We implement and evaluate the above solutions using software-radio platforms and off-the-shelf radios, and confirm their applicability in real-world settings.PhDElectrical Engineering: SystemsUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/133358/1/gkchai_1.pd

The Virtual Bus: A Network Architecture Designed to Support Modular-Redundant Distributed Periodic Real-Time Control Systems

The Virtual Bus network architecture uses physical layer switching and a combination of space- and time-division multiplexing to link segments of a partial mesh network together on schedule to temporarily form contention-free multi-hop, multi-drop simplex signalling paths, or 'virtual buses'. Network resources are scheduled and routed by a dynamic distributed resource allocation mechanism with self-forming and self-healing characteristics. Multiple virtual buses can coexist simultaneously in a single network, as the resources allocated to each bus are orthogonal in either space or time. The Virtual Bus architecture achieves deterministic delivery times for time-sensitive traffic over multi-hop partial mesh networks by employing true line-speed switching; delays of around 15ns at each switching point are demonstrated experimentally, and further reductions in switching delays are shown to be achievable. Virtual buses are inherently multicast, with delivery skew across multiple destinations proportional to the difference in equivalent physical length to each destination. The Virtual Bus architecture is not a purely theoretical concept; a small research platform has been constructed for development, testing and demonstration purposes

CarRing IV- Real-time Computer Network

Ob in der Automobil-, Avionik- oder Automatisierungstechnik, die Fortschritte in der Echtzeitkommunikation richten sich auf weitere Verbesserungen bereits existierender Lösungen. Im Kfz-Bereich führen die steigenden Zahlen computerbasierter Systeme, Anwendungen und Anschlüsse sowie die Verwendung mehrerer proprietärer Kommunikationsstandards zu einem immer komplexeren Kabelbaum. Ursächlich hierfür sind inkompatible Standards, wodurch nicht nur die Kosten, sondern auch das Gewicht und damit der Kraftstoffverbrauch negativ beeinflusst werden. Im ersten Teil der Dissertation wird das Echtzeitprotokoll von CarRing IV (CRIV) vorgestellt. Es bietet isochrone und harte Echtzeitgarantien, ohne dass eine netzwerkweite Synchronisation erforderlich ist. Mit bis zu 16 Knoten pro Ring kann ein CR-IV-Netz aus bis zu 256 Ringen bestehen, die durch Router miteinander verbunden sind. CR-IV verwendet ein reduziertes OSI-Modell (Schichten 1-3, 7), das für seine Anwendungsbereiche sowohl typisch als auch vorteilhaft ist. Außerdem unterstützt es sowohl ereignis- als auch zeitgesteuerte Kommunikationsparadigmen. Der Transparent-Modus ermöglicht es CR-IV, als Backbone für bestehende Netze zu verwenden, wodurch Inkompatibilitätsprobleme beseitigt werden und der Wechsel zu einer einheitlicheren Netzlösung erleichtert wird. Mit dieser Funktionalität können Nutzergeräte über ein CR-IV-Netz miteinander verbunden werden, ohne dass der Nutzer eingreifen oder etwas ändern muss. Durch Multicast unterstützt CRIV auch die Emulation von Feldbussen. Der zweite Teil der Dissertation stellt den anderen wichtigen Aspekt von CR-IV vor. Alle Schichten des OSI-Modells sind in einem FPGA mit Hardware Description Languages (HDLs) ohne Hard- oder Softprozessoren implementiert. Das Register-Transfer-Level (RTL)-Hardwaredesign von CR-IV wird mit einem neuen Ansatz erstellt, der am besten als tokenbasierter Datenfluss beschrieben werden kann. Der Ansatz ist sowohl vertikal als auch horizontal skalierbar. Er verwendet lose gekoppelte Processing Elements (PEs), die stateless arbeiten, sowie Arbiter/Speicherzuordnungspaare. Durch die granulare Kontrolle und die Aufteilung aller Aspekte einer Lösung eignet sich der Ansatz für die Implementierung anderer Software-Level-Lösungen in Hardware. Viele Testszenarios werden durchgeführt, um die in CR-IV erzielten Ergebnisse zu verdeutlichen und zu überprüfen. Diese Szenarien reichen von direkten Leistungsmessungen bis hin zu verhaltensspezifischen Tests. Zusätzlich wird eine Labor-Demo erstellt, die grundsätzlich auf ein Proof of Concept zielt. Die Demo stellt einen praktischen Test anstelle szenariospezifischer Tests dar. Alle Testszenarien und die Labor-Demo werden mit den Prototyp-Boards des Projekts durchgef¨uhrt, d.h. es sind keine Simulationstests. Die Ergebnisse stellen die realistischen Leistungen von CR-IV mit bis zu 13,61 Gbit/s dar.Whether be it automotive, avionics or automation, advances in their respective real-time communication technology focus on further improving preexisting solutions. For in-vehicle communication, the ever-increasing number of computer-based systems, applications and connections as well as the use of multiple proprietary communication standards results in an increasingly complex wiring harness. This is in-part due to those standards being incompatible with one another. In addition to cost, this also impacts weight, which in turn affects fuel consumption. The work presented in this thesis is in-part theoretical and in-part applied. The former is represented by a new protocol, while the latter corresponds to the protocol’s hardware implementation. In the first part of the thesis, the real-time communication protocol of CarRing IV (CR-IV) is presented. It provides isochronous and hard real-time guarantees without requiring network-wide clock synchronization. With up to 16 nodes per ring, a CR-IV network can consist of as many as 256 rings interconnected by routers. CR-IV uses a reduced OSI model (layers 1-3, 7), which is both typical of and preferable for its application areas. Moreover, it supports both event- and time-triggered communication paradigms. The transparent mode feature allows CR-IV to act as a backbone for existing networks, thereby addressing incompatibility concerns and easing the transition into a more unified network solution. Using this feature, user devices can communicate with one another via a CR-IV network without requiring user interference, or any user device or application changes. Combined with the protocol’s reliable multicast, the feature extends CR-IV’s capabilities to include field bus emulation. The second part of the thesis presents the other important aspect of CR-IV. All of its OSI model layers are implemented in a FPGA using Hardware Description Languages (HDLs) without relying-on or including any hard or soft processors. CR-IV’s Register-Transfer Level (RTL) hardware design is created using a new approach that can best be described as token-based data-flow. The approach is both vertically and horizontally scalable. It uses stateless and loosely coupled Processing Elements (PEs) as well as arbiter/memory allocation pairs. By having granular control and compartmentalizing every aspect of a solution, the approach lends itself to being used for implementing other software-level solutions in hardware. Many test scenarios are conducted to both highlight and examine the results achieved in CR-IV. Those scenarios range from direct performance measurements to behavior-specific tests. Moreover, a lab-demo is created that essentially amounts to a proof of concept. The demo represents a practical test as opposed to a scenariospecific one. Whether be it test scenarios or the lab-demo, all are carried-out using the project’s prototype boards, i.e. no simulation tests. The results obtained represent CR-IV’s real-world realistic outcomes with up to 13.61 Gbps

Vers la convergence de réseaux dans l'avionique

AFDX est le standard Ethernet commuté utilisé pour la transmission des flux avioniques. Pour des raisons de certification, le réseau AFDX déployé à présent dans les avions civils est très peu chargé. Cette thèse vise à étudier la possibilité envisagée par les avionneurs d’utiliser la bande passante AFDX restante pour transporter des flux non-avioniques additionnels (vidéo, audio, service). Ces flux ne doivent pas affecter les délais de transmission des flux avioniques. Pour multiplexer des flux avioniques et non-avioniques des politiques d’ordonnancement sont nécessaires au niveau des systèmes d’extrémité (end systems) et des commutateurs. Dans cette thèse, nous considérons l’exemple de la transmission sur AFDX de flux vidéo provenant des caméras de surveillance de l’avion. Le multiplexage des flux avioniques et vidéo est réalisé par l’introduction d’une table d’ordonnancement au niveau des end systems émetteurs et d’une politique de type SPQ dans les ports de sortie du commutateur. Cette solution préserve les contraintes temps-réel des flux avioniques, mais peut introduire des variations sur les délais de bout-en-bout des flux vidéo. Une allocation appropriée des flux avioniques dans la table d’ordonnancement peut réduire le retard d’émission des flux vidéo et ainsi, limiter les variations de délai. Nous proposons deux stratégies d’allocation des flux avioniques dans la table d’ordonnancement : une heuristique simple et une allocation optimale. L’allocation optimale est dérivée en résolvant un problème d’optimisation par contraintes qui minimise le retard d’émission des flux vidéo. Dans le cas des end systems moins chargés, l’allocation par heuristique est proche de l’optimale

System-on-chip architecture for secure sub-microsecond synchronization systems

213 p.En esta tesis, se pretende abordar los problemas que conlleva la protección cibernética del Precision Time Protocol (PTP). Éste es uno de los protocolos de comunicación más sensibles de entre los considerados por los organismos de estandarización para su aplicación en las futuras Smart Grids o redes eléctricas inteligentes. PTP tiene como misión distribuir una referencia de tiempo desde un dispositivo maestro al resto de dispositivos esclavos, situados dentro de una misma red, de forma muy precisa. El protocolo es altamente vulnerable, ya que introduciendo tan sólo un error de tiempo de un microsegundo, pueden causarse graves problemas en las funciones de protección del equipamiento eléctrico, o incluso detener su funcionamiento. Para ello, se propone una nueva arquitectura System-on-Chip basada en dispositivos reconfigurables, con el objetivo de integrar el protocolo PTP y el conocido estándar de seguridad MACsec para redes Ethernet. La flexibilidad que los modernos dispositivos reconfigurables proporcionan, ha sido aprovechada para el diseño de una arquitectura en la que coexisten procesamiento hardware y software. Los resultados experimentales avalan la viabilidad de utilizar MACsec para proteger la sincronización en entornos industriales, sin degradar la precisión del protocolo

Methods and Tools for Battery-free Wireless Networks

Embedding small wireless sensors into the environment allows for monitoring physical processes with high spatio-temporal resolutions. Today, these devices are equipped with a battery to supply them with power. Despite technological advances, the high maintenance cost and environmental impact of batteries prevent the widespread adoption of wireless sensors. Battery-free devices that store energy harvested from light, vibrations, and other ambient sources in a capacitor promise to overcome the drawbacks of (rechargeable) batteries, such as bulkiness, wear-out and toxicity. Because of low energy input and low storage capacity, battery-free devices operate intermittently; they are forced to remain inactive for most of the time charging their capacitor before being able to operate for a short time. While it is known how to deal with intermittency on a single device, the coordination and communication among groups of multiple battery-free devices remain largely unexplored. For the first time, the present thesis addresses this problem by proposing new methods and tools to investigate and overcome several fundamental challenges