Precise real-time monitoring of time-critical flows

Holzinger, Kilian; Stubbe, Henning; Biersack, Franz; Mariño, Angela Gonzalez; Kane, Abdoul; Lluis, Francisco Fons; Haigang, Zhang; Wild, Thomas; Herkersdorf, Andreas; Carle, Georg

doi:10.1145/3485983.3493356

Cited by 3 publications

(4 citation statements)

References 6 publications

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“…An initial design of the NHM was already presented in [12]. c) SmartNICs for Time Sensitive Domains: The vast majority of reported SmartNIC use-cases focus on data center applications.…”

Section: Related Workmentioning

confidence: 99%

SmartNIC-based Load Management and Network Health Monitoring for Time Sensitive Applications

Holzinger

Biersack

Stubbe

et al. 2022

NOMS 2022-2022 IEEE/IFIP Network Operations and Management Symposium

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Time sensitive network applications, for example in Intra-Vehicular Networks, aim to give predictable end-to-end latency guarantees. As a consequence, processing resources of involved host systems remain partially unused, because they are reserved for rare worst cases. This circumstance provides the opportunity to reduce dimensioning overheads by managing the load on the nodes flexibly within the network. In our proposed approach, a SmartNIC involving an FPGA-based load balancer achieves dynamic routing of flows whilst preserving end-to-end latency guarantees. A flow-oriented online network measurement component continuously supervises network traffic with regards to compliance to flow specifications and constraints such as bounded one-way delay, absence of packet loss, and jitter. We use the supervisor to enhance forwarding decisions on the data plane. Initial evaluation yields a saving potential of around 30 %. We showcase quick dynamic reconfiguration of the FPGA when triggered by real-time measurement of the one-way delay using realistic automotive network traffic.

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“…An initial design of the NHM was already presented in [12]. c) SmartNICs for Time Sensitive Domains: The vast majority of reported SmartNIC use-cases focus on data center applications.…”

Section: Related Workmentioning

confidence: 99%

SmartNIC-based Load Management and Network Health Monitoring for Time Sensitive Applications

Holzinger

Biersack

Stubbe

et al. 2022

NOMS 2022-2022 IEEE/IFIP Network Operations and Management Symposium

Self Cite

View full text Add to dashboard Cite

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“…Internally, the NS hosts a Finite State Machine (FSM) that takes as input the information from the SDNC and from an internal error detection unit and, based on this, decides the operation mode of the node and determines thus the internal configuration of the node. o Network Health Monitoring [74] o Load Management Layer [45] The output of this block is an error signal which will be transmitted to the Configurator Functional State Machine This error signal is transmitted using an error signaling protocol that distinguishes between three classes of errors: High, medium and low criticality.  Node Configurator: Static configuration of 8 signal groups in 6 different functional modes.…”

Section: Node Supervisor Architecture Overviewmentioning

confidence: 99%

Elastic Gateway Functional Safety Architecture and Deployment: A Case Study

et al. 2022

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The automotive industry has started its transformation towards Software-Defined Vehicles. This transformation is driven by the rise of the number of vehicle features, the high complexity of these features and their constraining availability requirements which affect all the players (Original Equipment Manufacturers, Tier1 and Tier2) of the sector. In the context of this transformation, our target, from functional safety point of view, is to, inter alia, provide an easy-to-use and safety-compliant execution and development flow and simplify the development and argumentation for safety by providing a) a pre-certified execution environment with safety design patterns and best-in-class safety measures and b) processes and tooling to minimize the system integrator's effort. Therefore, in this work we propose a top-down approach where we first define a New Generation In-Vehicle Network, NGIVN, capable of fulfilling the performance (e.g. high bandwidth, low end-2-end delay), safety-related availability (e.g. Autonomous Driving / Advanced Driver-Assistance Systems (AD/ADAS) up to SAE level 5) and safety requirements of modern vehicles. Also, we illustrate the advantages of this approach by deriving the functional and safety attributes of an Automotive Gateway SoC, named Elastic Gateway and destined to be part of the NGIVN. Through the deployment of the Elastic Gateway functional safety concept we demonstrate the flexibility provided by our approach with regards to the design of elements of the NGIVN.

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“…Freedom from Memory Interference [123] Safety island in safety critical hardware [124] Asil-decomposition based routing and scheduling in safety-critical time-sensitive networking [125] Network information flow [126] Coupling source routing with time-sensitive networking [127] Failure handling for time-sensitive networks using sdn and source routing [128] On the evaluation of the active queue management mechanisms [129] Achieving flexible, low-latency and 100gbps line-rate load balancing over ethernet on fpga [130] Smartnic-based load management and network health monitoring for time sensitive applications [131] Precise real-time monitoring of time-critical flows [132] Shortcutting Fast Failover Routes in the Data Plane [133] Fast failover in ethernet-based automotive networks […”

Section: Technologies Required In Future Ivns Functional Safety Safet...mentioning

confidence: 99%

“…Precise real-time monitoring of time-critical flows [132] Moongen: A scriptable high-speed packet generator [215] Efficient dynamic flow tracking for packet analyzers [216] High-performance packet processing and measurements [217] FloWatcher-DPDK: Lightweight line-rate flow-level monitoring in software [218] Fluent10g: A programmable FPGA-based network tester for multi-10-gigabit etherne [219]…”

Section: Traffic Generation and Monitoringmentioning

confidence: 99%

Contributions to the design, development and evaluation of network processors for automotive zonal gateway controllers

González Mariño

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(English) This PhD dissertation analyzes the evolution of vehicular networks and focuses on the main network processing platform integrated in them: the Gateway (GW). First, a thorough analysis of state of the art technologies involved in vehicular networks is performed, leading to the definition of the requirements of future network processing platforms. Then, the available options in the state of the art for network processing, both in industry and academia, are analyzed. This analysis shows a gap in this area: there is currently no architecture fulfilling all the requirements of future automotive GW controllers. Moreover, Hardware (HW) accelerators and custom processor design are identified as a key differentiation factor which boosts the performance of the devices. Linking the result of this analysis with the current trend towards application specific processors, this thesis proposes the novel Elastic Gateway (eGW) System on Chip (SoC) architecture as a high performance network processor for future zonal GW controllers. The proposed architecture aims at fulfilling the identified gap, advancing towards future GW SoC solutions. Elastic Gateway SoC concept aims at synthesizing a scalable and future-proof architecture embracing all new and already established functions and features demanded in a zonal gateway controller for the new era of mobility. The challenge now is not only to design the right processor that can meet the requirements available today, but also to make this design suitable for the future. For this reason, the modularity, flexibility, scalability and configurability of these future processors take, more than ever, a starring role in the early design stages. This thesis is also providing a complete lifecycle methodology for the design and validation of different network processing products based on the proposed eGW SoC architecture. Throughout this work the architecture is evaluated from a functional perspective, proving how the differefnt technologies required in future vehicular networks are integrated in eGW and how the previously defined requirements are met. Then, a proof of concept is implemented showing the viability of the proposed concept and methodology, providing details of the experimental results. The architecture is also evaluated from a scalability point of view, looking at HW cost and power consumption, proving that eGW is able to provide a high level of performance at a reasonable cost. Together, the eGW SoC concept and methodology become an alternative that can contribute to overcome the existing challenges, advancing over state of the art solutions. (Català) Aquesta tesi doctoral analitza l'evolució de les xarxes vehiculars i se centra en la principal plataforma de processament de xarxa integrada: el Gateway (GW). Primer es realitza una anàlisi exhaustiva de les tecnologies capdavanteres involucrades en les xarxes vehiculars, que porta a la definició dels requisits de les futures plataformes de processament de xarxes. Després, s'analitzen les opcions disponibles a l'estat de l'art per al processament de xarxes, tant a la indústria com al món acadèmic. Aquesta anàlisi mostra una bretxa en aquesta àrea: actualment no hi ha cap arquitectura que compleixi amb tots els requisits dels futurs controladors GW per a automòbils. A més, els acceleradors de hardware (HW) i el disseny de processadors dedicats s'identifiquen com un factor de diferenciació clau que augmenta el rendiment dels dispositius. Vinculant el resultat d'aquesta anàlisi amb la tendència actual cap als processadors d'aplicació específica, aquesta tesi proposa una nova arquitectura anomenada Elastic Gateway (eGW) System on Chip (SoC) com a processador de xarxes d'alt rendiment per als futurs controladors GW. L'arquitectura proposada té com a objectiu cobrir la bretxa identificada i avançar cap a futures solucions GW SoC. El concepte Elastic Gateway SoC té com a objectiu sintetitzar una arquitectura escalable i preparada per al futur que inclogui totes les funcions i característiques noves i ja establertes que s'exigeixen en un controlador \textit{gateway} per a la nova era de la mobilitat. El desafiament ara no és només dissenyar el processador correcte que pugui complir amb els requisits disponibles actualment, sinó també fer que aquest disseny sigui adequat per al futur. Per això, la modularitat, la flexibilitat, l'escalabilitat i la configurabilitat d'aquests futurs processadors cobren, més que mai, un paper protagonista en les primeres etapes de disseny. Aquesta tesi també proporciona una metodologia de cicle de vida completa per al disseny i la validació de diferents productes de processament de xarxa basats en larquitectura proposada de eGW SoC. Al llarg d'aquest treball s'avalua l'arquitectura des d'una perspectiva funcional, demostrant com s'integren a eGW les diferents tecnologies requerides en xarxes vehiculars futures i com es compleixen els requisits definits anteriorment. Per tant, s'implementa una prova de concepte que mostra la viabilitat del concepte i la metodologia proposada, proporcionant detalls dels resultats experimentals. L'arquitectura també s'avalua des del punt de vista de l'escalabilitat, considerant el cost de recursos HW i el consum d'energia, demostrant que eGW pot proporcionar un nivell alt de rendiment a un cost raonable. Tot plegat, el concepte i la metodologia d'eGW SoC proposen una alternativa que pot contribuir a superar els desafiaments existents, avançant sobre l'estat de l'art. (Español) Esta tesis doctoral analiza la evolución de las redes vehiculares y se centra en la principal plataforma de procesamiento de red integrada en ellas: el Gateway (GW). Primero se realiza un análisis exhaustivo de las tecnologías punteras involucradas en las redes vehiculares, que lleva a la definición de los requisitos de las futuras plataformas de procesamiento de redes. A continuación, se analizan las opciones disponibles en el estado del arte para el procesamiento de redes, tanto en la industria como en el mundo académico. Este análisis muestra una brecha en esta área: actualmente no existe ninguna arquitectura que cumpla con todos los requisitos de los futuros controladores GW para automóviles. Además, los aceleradores de hardware (HW) y el diseño de procesadores dedicados se identifican como un factor de diferenciación clave que aumenta el rendimiento de los dispositivos. Vinculando el resultado de este análisis con la tendencia actual hacia los procesadores de aplicación específica, esta tesis propone la nueva arquitectura Elastic Gateway (eGW) System on Chip (SoC) como un procesador de redes de alto rendimiento para los futuros controladores GW. La arquitectura propuesta tiene como objetivo cubrir la brecha identificada, avanzando hacia futuras soluciones GW SoC. El concepto Elastic Gateway SoC tiene como objetivo sintetizar una arquitectura escalable y preparada para el futuro que abarque todas las funciones y características nuevas y ya establecidas que se exigen en un controlador gateway para la nueva era de la movilidad. El desafío ahora no es solo diseñar el procesador correcto que pueda cumplir con los requisitos disponibles en la actualidad, sino también hacer que este diseño sea adecuado para el futuro. Por ello, la modularidad, flexibilidad, escalabilidad y configurabilidad de estos futuros procesadores cobran, más que nunca, un papel protagonista en las primeras etapas de diseño. Esta tesis también proporciona una metodología de ciclo de vida completa para el diseño y la validación de diferentes productos de procesamiento de red basados en la arquitectura propuesta de eGW SoC. A lo largo de este trabajo se evalúa la arquitectura desde una perspectiva funcional, demostrando cómo se integran en eGW las diferentes tecnologías requeridas en futuras redes vehiculares y cómo se cumplen los requisitos definidos anteriormente. Después, se implementa una prueba de concepto que muestra la viabilidad del concepto y la metodología propuesta, proporcionando detalles de los resultados experimentales. La arquitectura también se evalúa desde el punto de vista de la escalabilidad, considerando el coste de recursos HW y el consumo de energía, demostrando que eGW puede proporcionar un alto nivel de rendimiento a un coste razonable. En conjunto, el concepto y la metodología de eGW SoC proponen una alternativa que puede contribuir a superar los desafíos existentes, avanzando sobre el estado del arte.

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Precise real-time monitoring of time-critical flows

Cited by 3 publications

References 6 publications

SmartNIC-based Load Management and Network Health Monitoring for Time Sensitive Applications

SmartNIC-based Load Management and Network Health Monitoring for Time Sensitive Applications

Elastic Gateway Functional Safety Architecture and Deployment: A Case Study

Contributions to the design, development and evaluation of network processors for automotive zonal gateway controllers

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