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1. Switching in the Rain: Predictive Wireless x-haul Network Reconfiguration

   https://doi.org/10.1145/3570616  

   Kadota, Igor; Jacoby, Dror; Messer, Hagit; Zussman, Gil; Ostrometzky, Jonatan (December 2022, Proceedings of the ACM on Measurement and Analysis of Computing Systems)

   4G, 5G, and smart city networks often rely on microwave and millimeter-wave x-haul links. A major challenge associated with these high frequency links is their susceptibility to weather conditions. In particular, precipitation may cause severe signal attenuation, which significantly degrades the network performance. In this paper, we develop a Predictive Network Reconfiguration (PNR) framework that uses historical data to predict the future condition of each link and then prepares the network ahead of time for imminent disturbances. The PNR framework has two components: (i) an Attenuation Prediction (AP) mechanism; and (ii) a Multi-Step Network Reconfiguration (MSNR) algorithm. The AP mechanism employs an encoder-decoder Long Short-Term Memory (LSTM) model to predict the sequence of future attenuation levels of each link. The MSNR algorithm leverages these predictions to dynamically optimize routing and admission control decisions aiming to maximize network utilization, while preserving max-min fairness among the nodes using the network (e.g., base-stations) and preventing transient congestion that may be caused by switching routes. We train, validate, and evaluate the PNR framework using a dataset containing over 2 million measurements collected from a real-world city-scale backhaul network. The results show that the framework: (i) predicts attenuation with high accuracy, with an RMSE of less than 0.4 dB for a prediction horizon of 50 seconds; and (ii) can improve the instantaneous network utilization by more than 200% when compared to reactive network reconfiguration algorithms that cannot leverage information about future disturbances. 

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2. Switching in the rain: Predictive wireless x-haul network reconfiguration

   I. Kadota, D. Jacoby (June 2022, ArXivorg)

   Wireless x-haul networks rely on microwave and millimeter-wave links between 4G and/or 5G base-stations to support ultra-high data rate and ultra-low latency. A major challenge associated with these high frequency links is their susceptibility to weather conditions. In particular, precipitation may cause severe signal attenuation, which significantly degrades the network performance. In this paper, we develop a Predictive Network Reconfiguration (PNR) framework that uses historical data to predict the future condition of each link and then prepares the network ahead of time for imminent disturbances. The PNR framework has two components: (i) an Attenuation Prediction (AP) mechanism; and (ii) a Multi-Step Network Reconfiguration (MSNR) algorithm. The AP mechanism employs an encoderdecoder Long Short-Term Memory (LSTM) model to predict the sequence of future attenuation levels of each link. The MSNR algorithm leverages these predictions to dynamically optimize routing and admission control decisions aiming to maximize network utilization, while preserving max-min fairness among the base-stations sharing the network and preventing transient congestion that may be caused by re-routing. We train, validate, and evaluate the PNR framework using a dataset containing over 2 million measurements collected from a real-world city-scale backhaul network. The results show that the framework: (i) predicts attenuation with high accuracy, with an RMSE of less than 0.4 dB for a prediction horizon of 50 seconds; and (ii) can improve the instantaneous network utilization by more than 200% when compared to reactive network reconfiguration algorithms that cannot leverage information about future disturbances 

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3. Virtual Function Placement and Traffic Steering over 5G Multi-Technology Networks

   https://doi.org/10.1109/NETSOFT.2018.8460097  

   Akhtar, Nabeel; Matta, Ibrahim; Raza, Ali; Goratti, Leonardo; Braun, Torsten; Esposito, Flavio (June 2018, 2018 4th IEEE Conference on Network Softwarization and Workshops (NetSoft))

   Next-generation mobile networks (5G and beyond) are expected to provide higher data rates and ultra-low latency in support of demanding applications, such as virtual and augmented reality, robots and drones, etc. To meet these stringent requirements, edge computing constitutes a central piece of the solution architecture wherein functional components of an application can be deployed over the edge network so as to reduce bandwidth demand over the core network while providing ultra-low latency communication to users. In this paper, we investigate the joint optimal placement of virtual service chains consisting of virtual application functions (components) and the steering of traffic through them, over a 5G multi-technology edge network model consisting of both Ethernet and mmWave links. This problem is NP-hard. We provide a comprehensive “microscopic" binary integer program to model the system, along with a heuristic that is one order of magnitude faster than solving the corresponding binary integer program. Extensive evaluations demonstrate the benefits of managing virtual service chains (by distributing them over the edge network) compared to a baseline “middlebox" approach in terms of overall admissible virtual capacity. We observe significant gains when deploying mmWave links that complement the Ethernet physical infrastructure. Moreover, most of the gains are attributed to only 30% of these mmWave links. 

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4. Fast and Efficient Scaling for Microservices with SurgeGuard

   https://doi.org/10.1109/SC41406.2024.00103  

   Ghosh, Anyesha; Yadwadkar, Neeraja J; Erez, Mattan (November 2024, IEEE)

   The microservice architecture is increasingly popular for flexible, large-scale online applications. However, existing resource management mechanisms incur high latency in detecting Quality of Service (QoS) violations, and hence, fail to allocate resources effectively under commonly-observed varying load conditions. This results in over-allocation coupled with a late response that increase both the total cost of ownership and the magnitude of each QoS violation event. We present SurgeGuard, a decentralized resource controller for microservice applications specifically designed to guard application QoS during surges in load and network latency. SurgeGuard uses the key insight that for rapid detection and effective management of QoS violations, the controller must be aware of any available slack in latency and communication patterns between microservices within a task-graph. Our experiments show that for the workloads in DeathStarBench, SurgeGuard on average reduces the combined violation magnitude and duration by 61.1% and 93.7%, respectively, compared to the well-known Parties and Caladan algorithms, and requires 8% fewer resources than Parties 

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5. A Reality-Conforming Approach for QoS Performance Analysis of AFDX in Cyber-Physical Avionics Systems

   https://doi.org/10.1109/IWQOS52092.2021.9521335  

   Zhou, Boyang; Cheng, Liang (June 2021, 2021 IEEE/ACM 29th International Symposium on Quality of Service (IWQOS))

   AFDX (Avionics Full Duplex Switched Ethernet) is developed to support mission-critical communications while providing deterministic Quality of Service (QoS) across cyber-physical avionics systems. Currently, AFDX utilizes FP/FIFO QoS mechanisms to guarantee its real-time performance. To analyze the real-time performance of avionic systems in their design processes, existing work analyzes the deterministic delay bound of AFDX using NC (Network Calculus). However, existing analytical work is based on an unrealistic assumption leading to assumed worst cases that may not be achievable in reality. In this paper, we present a family of algorithms that can search for realistic worst-case delay scenarios in both preemptive and non-preemptive situations. Then we integrate the proposed algorithms with NC and apply our approach to analyzing tandem AFDX networks. Our reality-conforming approach yields tighter delay bound estimations than the state of the art. When there are 100 virtual links in AFDX networks, our method can provide delay bounds more than 25% tighter than those calculated by the state of the art in our evaluation. Moreover, when using our reality-conforming method in the design process, it leads to 27.2% increase in the number of virtual links accommodated by the network in the tandem scenario. 

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