Your search keyword '"Cheng, Xiangle"' showing total 105 results

1. Atom: Neural Traffic Compression with Spatio-Temporal Graph Neural Networks

Author

Almasan, Paul, Rusek, Krzysztof, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Cabellos-Aparicio, Albert, and Barlet-Ros, Pere

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Storing network traffic data is key to efficient network management; however, it is becoming more challenging and costly due to the ever-increasing data transmission rates, traffic volumes, and connected devices. In this paper, we explore the use of neural architectures for network traffic compression. Specifically, we consider a network scenario with multiple measurement points in a network topology. Such measurements can be interpreted as multiple time series that exhibit spatial and temporal correlations induced by network topology, routing, or user behavior. We present \textit{Atom}, a neural traffic compression method that leverages spatial and temporal correlations present in network traffic. \textit{Atom} implements a customized spatio-temporal graph neural network design that effectively exploits both types of correlations simultaneously. The experimental results show that \textit{Atom} can outperform GZIP's compression ratios by 50\%-65\% on three real-world networks., Comment: 7 pages, 6 figures, 2nd International Workshop on Graph Neural Networking (GNNet '23)

Published

2023

2. GraphCC: A Practical Graph Learning-based Approach to Congestion Control in Datacenters

Author

Bernárdez, Guillermo, Suárez-Varela, José, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Computer Science - Multiagent Systems

Abstract

Congestion Control (CC) plays a fundamental role in optimizing traffic in Data Center Networks (DCN). Currently, DCNs mainly implement two main CC protocols: DCTCP and DCQCN. Both protocols -- and their main variants -- are based on Explicit Congestion Notification (ECN), where intermediate switches mark packets when they detect congestion. The ECN configuration is thus a crucial aspect on the performance of CC protocols. Nowadays, network experts set static ECN parameters carefully selected to optimize the average network performance. However, today's high-speed DCNs experience quick and abrupt changes that severely change the network state (e.g., dynamic traffic workloads, incast events, failures). This leads to under-utilization and sub-optimal performance. This paper presents GraphCC, a novel Machine Learning-based framework for in-network CC optimization. Our distributed solution relies on a novel combination of Multi-agent Reinforcement Learning (MARL) and Graph Neural Networks (GNN), and it is compatible with widely deployed ECN-based CC protocols. GraphCC deploys distributed agents on switches that communicate with their neighbors to cooperate and optimize the global ECN configuration. In our evaluation, we test the performance of GraphCC under a wide variety of scenarios, focusing on the capability of this solution to adapt to new scenarios unseen during training (e.g., new traffic workloads, failures, upgrades). We compare GraphCC with a state-of-the-art MARL-based solution for ECN tuning -- ACC -- and observe that our proposed solution outperforms the state-of-the-art baseline in all of the evaluation scenarios, showing improvements up to $20\%$ in Flow Completion Time as well as significant reductions in buffer occupancy ($38.0-85.7\%$)., Comment: 11 pages, 7 figures, 2 tables

Published

2023

3. Neural Quantile Optimization for Edge-Cloud Networking

Author

Du, Bin, Zhang, He, Cheng, Xiangle, and Zhang, Lei

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Artificial Intelligence

Abstract

We seek the best traffic allocation scheme for the edge-cloud computing network that satisfies constraints and minimizes the cost based on burstable billing. First, for a fixed network topology, we formulate a family of integer programming problems with random parameters describing the various traffic demands. Then, to overcome the difficulty caused by the discrete feature of the problem, we generalize the Gumbel-softmax reparameterization method to induce an unconstrained continuous optimization problem as a regularized continuation of the discrete problem. Finally, we introduce the Gumbel-softmax sampling network to solve the optimization problems via unsupervised learning. The network structure reflects the edge-cloud computing topology and is trained to minimize the expectation of the cost function for unconstrained continuous optimization problems. The trained network works as an efficient traffic allocation scheme sampler, remarkably outperforming the random strategy in feasibility and cost function value. Besides testing the quality of the output allocation scheme, we examine the generalization property of the network by increasing the time steps and the number of users. We also feed the solution to existing integer optimization solvers as initial conditions and verify the warm-starts can accelerate the short-time iteration process. The framework is general with solid performance, and the decoupled feature of the random neural networks is adequate for practical implementations.

Published

2023

4. MAGNNETO: A Graph Neural Network-based Multi-Agent system for Traffic Engineering

Author

Bernárdez, Guillermo, Suárez-Varela, José, López, Albert, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning, Computer Science - Multiagent Systems

Abstract

Current trends in networking propose the use of Machine Learning (ML) for a wide variety of network optimization tasks. As such, many efforts have been made to produce ML-based solutions for Traffic Engineering (TE), which is a fundamental problem in ISP networks. Nowadays, state-of-the-art TE optimizers rely on traditional optimization techniques, such as Local search, Constraint Programming, or Linear programming. In this paper, we present MAGNNETO, a distributed ML-based framework that leverages Multi-Agent Reinforcement Learning and Graph Neural Networks for distributed TE optimization. MAGNNETO deploys a set of agents across the network that learn and communicate in a distributed fashion via message exchanges between neighboring agents. Particularly, we apply this framework to optimize link weights in OSPF, with the goal of minimizing network congestion. In our evaluation, we compare MAGNNETO against several state-of-the-art TE optimizers in more than 75 topologies (up to 153 nodes and 354 links), including realistic traffic loads. Our experimental results show that, thanks to its distributed nature, MAGNNETO achieves comparable performance to state-of-the-art TE optimizers with significantly lower execution times. Moreover, our ML-based solution demonstrates a strong generalization capability to successfully operate in new networks unseen during training., Comment: IEEE Transactions on Cognitive Communications and Networking (2023). arXiv admin note: text overlap with arXiv:2109.01445

Published

2023

5. Leveraging Spatial and Temporal Correlations for Network Traffic Compression

Author

Almasan, Paul, Rusek, Krzysztof, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Cabellos-Aparicio, Albert, and Barlet-Ros, Pere

Subjects

Computer Science - Networking and Internet Architecture

Abstract

The deployment of modern network applications is increasing the network size and traffic volumes at an unprecedented pace. Storing network-related information (e.g., traffic traces) is key to enable efficient network management. However, this task is becoming more challenging due to the ever-increasing data transmission rates and traffic volumes. In this paper, we present a novel method for network traffic compression that exploits spatial and temporal patterns naturally present in network traffic. We consider a realistic scenario where traffic measurements are performed at multiple links of a network topology using tools like SNMP or NetFlow. Such measurements can be seen as multiple time series that exhibit spatial and temporal correlations induced by the network topology, routing or user behavior. Our method leverages graph learning methods to effectively exploit both types of correlations for traffic compression. The experimental results show that our solution is able to outperform GZIP, the \textit{de facto} traffic compression method, improving by 50\%-65\% the compression ratio on three real-world networks., Comment: 11 pages, 14 figures

Published

2023

6. RouteNet-Fermi: Network Modeling with Graph Neural Networks

Author

Ferriol-Galmés, Miquel, Paillisse, Jordi, Suárez-Varela, José, Rusek, Krzysztof, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Network models are an essential block of modern networks. For example, they are widely used in network planning and optimization. However, as networks increase in scale and complexity, some models present limitations, such as the assumption of Markovian traffic in queuing theory models, or the high computational cost of network simulators. Recent advances in machine learning, such as Graph Neural Networks (GNN), are enabling a new generation of network models that are data-driven and can learn complex non-linear behaviors. In this paper, we present RouteNet-Fermi, a custom GNN model that shares the same goals as Queuing Theory, while being considerably more accurate in the presence of realistic traffic models. The proposed model predicts accurately the delay, jitter, and packet loss of a network. We have tested RouteNet-Fermi in networks of increasing size (up to 300 nodes), including samples with mixed traffic profiles -- e.g., with complex non-Markovian models -- and arbitrary routing and queue scheduling configurations. Our experimental results show that RouteNet-Fermi achieves similar accuracy as computationally-expensive packet-level simulators and scales accurately to larger networks. Our model produces delay estimates with a mean relative error of 6.24% when applied to a test dataset of 1,000 samples, including network topologies one order of magnitude larger than those seen during training. Finally, we have also evaluated RouteNet-Fermi with measurements from a physical testbed and packet traces from a real-life network., Comment: This paper has been accepted for publication at IEEE/ACM Transactions on Networking 2023 (DOI: 10.1109/TNET.2023.3269983). \copyright 2023 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses

Published

2022

7. Network Digital Twin: Context, Enabling Technologies and Opportunities

Author

Almasan, Paul, Ferriol-Galmés, Miquel, Paillisse, Jordi, Suárez-Varela, José, Perino, Diego, López, Diego, Perales, Antonio Agustin Pastor, Harvey, Paul, Ciavaglia, Laurent, Wong, Leon, Ram, Vishnu, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Cabellos-Aparicio, Albert, and Barlet-Ros, Pere

Subjects

Computer Science - Networking and Internet Architecture

Abstract

The proliferation of emergent network applications (e.g., telesurgery, metaverse) is increasing the difficulty of managing modern communication networks. These applications entail stringent network requirements (e.g., ultra-low deterministic latency), which hinders network operators to manage their resources efficiently. In this article, we introduce the network digital twin (NDT), a renovated concept of classical network modeling tools whose goal is to build accurate data-driven network models that can operate in real-time. We describe the general architecture of the NDT and argue that modern machine learning (ML) technologies enable building some of its core components. Then, we present a case study that leverages a ML-based NDT for network performance evaluation and apply it to routing optimization in a QoS-aware use case. Lastly, we describe some key open challenges and research opportunities yet to be explored to achieve effective deployment of NDTs in real-world networks., Comment: 7 pages, 4 figures. arXiv admin note: text overlap with arXiv:2201.01144

Published

2022

8. Neural quantile optimization for edge–cloud networking

Author

Du, Bin, Zhang, He, Cheng, Xiangle, and Zhang, Lei

Published

2024

9. GraphCC: A practical graph learning-based approach to Congestion Control in datacenters

Author

Bernárdez, Guillermo, Suárez-Varela, José, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Published

2025

10. Convergence analysis of discrete high-index saddle dynamics

Author

Luo, Yue, Zheng, Xiangcheng, Cheng, Xiangle, and Zhang, Lei

Subjects

Mathematics - Numerical Analysis, 37M05, 37N30, 65L20

Abstract

Saddle dynamics is a time continuous dynamics to efficiently compute the any-index saddle points and construct the solution landscape. In practice, the saddle dynamics needs to be discretized for numerical computations, while the corresponding numerical analysis are rarely studied in the literature, especially for the high-index cases. In this paper we propose the convergence analysis of discrete high-index saddle dynamics. To be specific, we prove the local linear convergence rates of numerical schemes of high-index saddle dynamics, which indicates that the local curvature in the neighborhood of the saddle point and the accuracy of computing the eigenfunctions are main factors that affect the convergence of discrete saddle dynamics. The proved results serve as compensations for the convergence analysis of high-index saddle dynamics and are substantiated by numerical experiments.

Published

2022

11. RouteNet-Erlang: A Graph Neural Network for Network Performance Evaluation

Author

Ferriol-Galmés, Miquel, Rusek, Krzysztof, Suárez-Varela, José, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning

Abstract

Network modeling is a fundamental tool in network research, design, and operation. Arguably the most popular method for modeling is Queuing Theory (QT). Its main limitation is that it imposes strong assumptions on the packet arrival process, which typically do not hold in real networks. In the field of Deep Learning, Graph Neural Networks (GNN) have emerged as a new technique to build data-driven models that can learn complex and non-linear behavior. In this paper, we present \emph{RouteNet-Erlang}, a pioneering GNN architecture designed to model computer networks. RouteNet-Erlang supports complex traffic models, multi-queue scheduling policies, routing policies and can provide accurate estimates in networks not seen in the training phase. We benchmark RouteNet-Erlang against a state-of-the-art QT model, and our results show that it outperforms QT in all the network scenarios., Comment: arXiv admin note: text overlap with arXiv:2110.01261

Published

2022

12. Accelerating Deep Reinforcement Learning for Digital Twin Network Optimization with Evolutionary Strategies

Author

Güemes-Palau, Carlos, Almasan, Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning

Abstract

The recent growth of emergent network applications (e.g., satellite networks, vehicular networks) is increasing the complexity of managing modern communication networks. As a result, the community proposed the Digital Twin Networks (DTN) as a key enabler of efficient network management. Network operators can leverage the DTN to perform different optimization tasks (e.g., Traffic Engineering, Network Planning). Deep Reinforcement Learning (DRL) showed a high performance when applied to solve network optimization problems. In the context of DTN, DRL can be leveraged to solve optimization problems without directly impacting the real-world network behavior. However, DRL scales poorly with the problem size and complexity. In this paper, we explore the use of Evolutionary Strategies (ES) to train DRL agents for solving a routing optimization problem. The experimental results show that ES achieved a training time speed-up of 128 and 6 for the NSFNET and GEANT2 topologies respectively., Comment: 5 pages, 5 figures

Published

2022

13. Digital Twin Network: Opportunities and Challenges

Author

Almasan, Paul, Ferriol-Galmés, Miquel, Paillisse, Jordi, Suárez-Varela, José, Perino, Diego, López, Diego, Perales, Antonio Agustin Pastor, Harvey, Paul, Ciavaglia, Laurent, Wong, Leon, Ram, Vishnu, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Cabellos-Aparicio, Albert, and Barlet-Ros, Pere

Subjects

Computer Science - Networking and Internet Architecture

Abstract

The proliferation of emergent network applications (e.g., AR/VR, telesurgery, real-time communications) is increasing the difficulty of managing modern communication networks. These applications typically have stringent requirements (e.g., ultra-low deterministic latency), making it more difficult for network operators to manage their network resources efficiently. In this article, we propose the Digital Twin Network (DTN) as a key enabler for efficient network management in modern networks. We describe the general architecture of the DTN and argue that recent trends in Machine Learning (ML) enable building a DTN that efficiently and accurately mimics real-world networks. In addition, we explore the main ML technologies that enable developing the components of the DTN architecture. Finally, we describe the open challenges that the research community has to address in the upcoming years in order to enable the deployment of the DTN in real-world scenarios., Comment: 7 pages, 4 figures

Published

2022

14. Graph Neural Networks for Communication Networks: Context, Use Cases and Opportunities

Author

Suárez-Varela, José, Almasan, Paul, Ferriol-Galmés, Miquel, Rusek, Krzysztof, Geyer, Fabien, Cheng, Xiangle, Shi, Xiang, Xiao, Shihan, Scarselli, Franco, Cabellos-Aparicio, Albert, and Barlet-Ros, Pere

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing

Abstract

Graph neural networks (GNN) have shown outstanding applications in many fields where data is fundamentally represented as graphs (e.g., chemistry, biology, recommendation systems). In this vein, communication networks comprise many fundamental components that are naturally represented in a graph-structured manner (e.g., topology, configurations, traffic flows). This position article presents GNNs as a fundamental tool for modeling, control and management of communication networks. GNNs represent a new generation of data-driven models that can accurately learn and reproduce the complex behaviors behind real networks. As a result, such models can be applied to a wide variety of networking use cases, such as planning, online optimization, or troubleshooting. The main advantage of GNNs over traditional neural networks lies in its unprecedented generalization capabilities when applied to other networks and configurations unseen during training, which is a critical feature for achieving practical data-driven solutions for networking. This article comprises a brief tutorial on GNNs and their possible applications to communication networks. To showcase the potential of this technology, we present two use cases with state-of-the-art GNN models respectively applied to wired and wireless networks. Lastly, we delve into the key open challenges and opportunities yet to be explored in this novel research area.

Published

2021

15. Physics Constrained Flow Neural Network for Short-Timescale Predictions in Data Communications Networks

Author

Cheng, Xiangle, He, James, Xiao, Shihan, Zhang, Yingxue, Chen, Zhitang, Poupart, Pascal, and Li, Fenglin

Subjects

Computer Science - Machine Learning, Computer Science - Networking and Internet Architecture

Abstract

Machine learning is gaining growing momentum in various recent models for the dynamic analysis of information flows in data communications networks. These preliminary models often rely on off-the-shelf learning models to predict from historical statistics while disregarding the physics governing the generating behaviors of these flows. This paper instead introduces Flow Neural Network (FlowNN) to improve the feature representation with learned physical bias. This is implemented by an induction layer, working upon the embedding layer, to impose the physics connected data correlations, and a self-supervised learning strategy with stop-gradient to make the learned physics universal. For the short-timescale network prediction tasks, FlowNN achieves 17% - 71% of loss decrease than the state-of-the-art baselines on both synthetic and real-world networking datasets, which shows the strength of this new approach.

Published

2021

16. Generation of quasi-traveling waves in a finite rectangular membrane with two internal viscoelastic line supports

Author

Cheng, Xiangle, McFarland, D. Michael, Lu, Huancai, Zhou, Daren, and Hua, Xia

Published

2024

17. ENERO: Efficient Real-Time WAN Routing Optimization with Deep Reinforcement Learning

Author

Almasan, Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning

Abstract

Wide Area Networks (WAN) are a key infrastructure in today's society. During the last years, WANs have seen a considerable increase in network's traffic and network applications, imposing new requirements on existing network technologies (e.g., low latency and high throughput). Consequently, Internet Service Providers (ISP) are under pressure to ensure the customer's Quality of Service and fulfill Service Level Agreements. Network operators leverage Traffic Engineering (TE) techniques to efficiently manage network's resources. However, WAN's traffic can drastically change during time and the connectivity can be affected due to external factors (e.g., link failures). Therefore, TE solutions must be able to adapt to dynamic scenarios in real-time. In this paper we propose Enero, an efficient real-time TE solution based on a two-stage optimization process. In the first one, Enero leverages Deep Reinforcement Learning (DRL) to optimize the routing configuration by generating a long-term TE strategy. To enable efficient operation over dynamic network scenarios (e.g., when link failures occur), we integrated a Graph Neural Network into the DRL agent. In the second stage, Enero uses a Local Search algorithm to improve DRL's solution without adding computational overhead to the optimization process. The experimental results indicate that Enero is able to operate in real-world dynamic network topologies in 4.5 seconds on average for topologies up to 100 edges., Comment: 12 pages, 9 figures

Published

2021

18. Is Machine Learning Ready for Traffic Engineering Optimization?

Author

Bernárdez, Guillermo, Suárez-Varela, José, López, Albert, Wu, Bo, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Traffic Engineering (TE) is a basic building block of the Internet. In this paper, we analyze whether modern Machine Learning (ML) methods are ready to be used for TE optimization. We address this open question through a comparative analysis between the state of the art in ML and the state of the art in TE. To this end, we first present a novel distributed system for TE that leverages the latest advancements in ML. Our system implements a novel architecture that combines Multi-Agent Reinforcement Learning (MARL) and Graph Neural Networks (GNN) to minimize network congestion. In our evaluation, we compare our MARL+GNN system with DEFO, a network optimizer based on Constraint Programming that represents the state of the art in TE. Our experimental results show that the proposed MARL+GNN solution achieves equivalent performance to DEFO in a wide variety of network scenarios including three real-world network topologies. At the same time, we show that MARL+GNN can achieve significant reductions in execution time (from the scale of minutes with DEFO to a few seconds with our solution)., Comment: To appear at IEEE ICNP 2021

Published

2021

19. One-dimensional granular chains as transmitted force attenuators

Author

Zhou, Zhenjiang, McFarland, D. Michael, Cheng, Xiangle, Lu, Huancai, and Vakakis, Alexander F.

Published

2023

20. Building a Digital Twin for network optimization using Graph Neural Networks

Author

Ferriol-Galmés, Miquel, Suárez-Varela, José, Paillissé, Jordi, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Published

2022

21. ENERO: Efficient real-time WAN routing optimization with Deep Reinforcement Learning

Author

Almasan, Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet-Ros, Pere, and Cabellos-Aparicio, Albert

Published

2022

22. Localization of travelling and standing waves in a circular membrane coupled to a continuous viscoelastic support

Author

Cheng, Xiangle, McFarland, D. Michael, Lu, Huancai, Vakakis, Alexander F., and Bergman, Lawrence A.

Published

2022

23. Modeling and Characterization of Complex Dynamical Properties of Railway Ballast.

Author

Hua, Xia, Zatar, Wael, Cheng, Xiangle, Chen, Gang S., She, Yini, Xu, Xiaotian, and Liao, Zhicheng

Subjects

GROUND penetrating radar, SIGNAL processing, DYNAMICAL systems, HYSTERESIS, SYSTEM dynamics

Abstract

The nonlinear mechanical properties of ballasted tracks along railways result in complex dynamics of the vehicle–track systems. Employing localized characterization of ballast and a simplified model might underestimate the vehicle–track system's dynamical responses and safety. This paper presents a new dynamical stiffness model of railway ballast by incorporating the ballast's time-varying, nonlinear viscoelastic, and elastoplastic properties. The new nonlinear stiffness model is a versatile tool that comprehensively characterizes the ballast characteristics of displacement-dependent stiffness, frequency-dependent stiffness, hysteresis, and time/space-varying features. These features, widely reported in previous experimental research, can now be effectively understood. Conventionally, to characterize time/space-varying characteristics of ballast along the track, ground-penetrating radar (GPR) has been used as the most efficient approach to survey railway networks quickly and to infer track dynamical properties. Aiming to improve the present technique for characterizing time/space-varying properties of ballast stiffness by using a GPR signal, the adaptive optimal kernel time–frequency representation (AOKTFR) method is used to process a typical GPR signal from a railway ballast scanning. It is found that the results of AOKTFR exhibit a clear time-varying pattern and precise frequency modulation. In contrast, the conventional time–frequency methods failed to give a clear time-varying pattern. The results illustrate that AOKTFR is a practical approach for processing the time-varying nonlinear signal of GPR and correlating it with the time-varying nonlinear stiffness of ballast. [ABSTRACT FROM AUTHOR]

Published

2024

24. Path Tracking Control for Four-Wheel Independent Steering and Driving Vehicles Based on Improved Deep Reinforcement Learning.

Author

Hua, Xia, Zhang, Tengteng, Cheng, Xiangle, and Ning, Xiaobin

Subjects

DEEP reinforcement learning, REINFORCEMENT learning, GENERALIZATION, NONLINEAR equations, MOTOR vehicle driving

Abstract

We propose a compound control framework to improve the path tracking accuracy of a four-wheel independent steering and driving (4WISD) vehicle in complex environments. The framework consists of a deep reinforcement learning (DRL)-based auxiliary controller and a dual-layer controller. Samples in the 4WISD vehicle control framework have the issues of skewness and sparsity, which makes it difficult for the DRL to converge. We propose a group intelligent experience replay (GER) mechanism that non-dominantly sorts the samples in the experience buffer, which facilitates within-group and between-group collaboration to achieve a balance between exploration and exploitation. To address the generalization problem in the complex nonlinear dynamics of 4WISD vehicles, we propose an actor-critic architecture based on the method of two-stream information bottleneck (TIB). The TIB method is used to remove redundant information and extract high-dimensional features from the samples, thereby reducing generalization errors. To alleviate the overfitting of DRL to known data caused by IB, the reverse information bottleneck (RIB) alters the optimization objective of IB, preserving the discriminative features that are highly correlated with actions and improving the generalization ability of DRL. The proposed method significantly improves the convergence and generalization capabilities of DRL, while effectively enhancing the path tracking accuracy of 4WISD vehicles in high-speed, large-curvature, and complex environments. [ABSTRACT FROM AUTHOR]

Published

2024

25. Reconstruction of waves traveling in a nonlinear granular chain from acoustic measurements

Author

Cheng, Xiangle, Lu, Huancai, and McFarland, D. Michael

Published

2021

26. Experimental Validation of Reconstruction of Sound Source Radiation in an Underwater Half-Space Bounded by a Water-Air Interface

Author

Chen, Zhimin, primary, Zhou, Daren, additional, Lou, Jingjun, additional, Peng, Min, additional, Xiao, Yongxiong, additional, Cheng, Xiangle, additional, and Ru, Zeyu, additional

Published

2024

27. Co-existing complexity-induced traveling wave transmission and vibration localization in Euler-Bernoulli beams

Author

Cheng, Xiangle, Bergman, Lawrence A., McFarland, D. Michael, Tan, Chin An, Vakakis, Alexander F., and Lu, Huancai

Published

2019

28. Atom: Neural Traffic Compression with Spatio-Temporal Graph Neural Networks

Author

Almasan, Paul, primary, Rusek, Krzysztof, additional, Xiao, Shihan, additional, Shi, Xiang, additional, Cheng, Xiangle, additional, Cabellos-Aparicio, Albert, additional, and Barlet-Ros, Pere, additional

Published

2023

29. Separation of traveling and standing waves in a finite dispersive string with partial or continuous viscoelastic foundation

Author

Cheng, Xiangle, Blanchard, Antoine, Tan, Chin An, Lu, Huancai, Bergman, Lawrence A., McFarland, D. Michael, and Vakakis, Alexander F.

Published

2017

30. Dynamic simulation of a motor longitudinally mounted on a centralized electric drive systems for pure electric vehicles under torque ripple and transmission error excitations

Author

Liao, Zhicheng, primary, Hua, Xia, additional, Cheng, Xiangle, additional, Ning, Xiaobin, additional, Liu, Zhengqing, additional, and Chen, Gang, additional

Published

2023

31. Graph Neural Networks for Communication Networks: Context, Use Cases and Opportunities

Author

Suárez-Varela, José, primary, Almasan, Paul, additional, Ferriol-Galmés, Miquel, additional, Rusek, Krzysztof, additional, Geyer, Fabien, additional, Cheng, Xiangle, additional, Shi, Xiang, additional, Xiao, Shihan, additional, Scarselli, Franco, additional, Cabellos-Aparicio, Albert, additional, and Barlet-Ros, Pere, additional

Published

2023

32. Performance-oriented digital twins for packet and optical networks

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Cabellos Aparicio, Alberto, Janz, Christopher, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Barlet Ros, Pere, Paillissé Vilanova, Jordi, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Guo, Aihua, Perino, Diego, Lopez, Diego, Pastor Perales, Antonio Agustín, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Cabellos Aparicio, Alberto, Janz, Christopher, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Barlet Ros, Pere, Paillissé Vilanova, Jordi, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Guo, Aihua, Perino, Diego, Lopez, Diego, and Pastor Perales, Antonio Agustín

Abstract

This draft introduces the concept of a Network Digital Twin (NDT), including the architecture as well as the interfaces. Then two specific instances of the NDT are introduced, the first one for packet networks. This produces performance estimates (delay, jitter, loss) for a packet network with a specified topology, traffic demand, and routing and scheduling configuration. Second, a NDT for optical networks, this produces transmission performance estimates of an optical network with specified optical service topologies and network equipment types, topology and status., Preprint

Published

2023

33. Graph neural networks for communication networks: context, use cases and opportunities

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Suárez-Varela Maciá, José Rafael, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Rusek, Krzysztof, Geyer, Fabien, Cheng, Xiangle, Shi, Xiang, Xiao, Shihan, Scarselli, Franco, Cabellos Aparicio, Alberto, Barlet Ros, Pere, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Suárez-Varela Maciá, José Rafael, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Rusek, Krzysztof, Geyer, Fabien, Cheng, Xiangle, Shi, Xiang, Xiao, Shihan, Scarselli, Franco, Cabellos Aparicio, Alberto, and Barlet Ros, Pere

Abstract

Graph neural networks (GNN) have shown outstanding applications in fields where data is essentially represented as graphs (e.g., chemistry, biology, recommendation systems). In this vein, communication networks comprise many fundamental components that are naturally represented in a graph-structured manner (e.g., topology, routing, signal interference). This position article presents GNNs as a fundamental tool for modeling, control and management of communication networks. GNNs represent a new generation of data-driven models that can accurately learn and reproduce the complex behaviors behind real-world networks. As a result, these models can be applied to a wide variety of networking use cases, such as planning, online optimization, or troubleshooting. The main advantage of GNNs over traditional neural networks lies in their unprecedented generalization capabilities when applied to other networks and configurations unseen during training. This is a critical feature for achieving practical data-driven solutions for networking. This article starts with a brief tutorial on GNNs and some potential applications to communication networks. Then, it presents two state-of-the-art GNN models respectively applied to wired and wireless networks. Lastly, it delves into the key open challenges and opportunities yet to be explored in this novel research area., This publication is part of the Spanish I+D+i project TRAINER-A (ref. PID2020-118011GB-C21), funded by MCIN/AEI/10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA) and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2023

34. RouteNet-Fermi: network modeling with graph neural networks

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Ferriol Galmés, Miquel, Paillissé Vilanova, Jordi, Suárez-Varela Maciá, José Rafael, Rusek, Krzysztof, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Ferriol Galmés, Miquel, Paillissé Vilanova, Jordi, Suárez-Varela Maciá, José Rafael, Rusek, Krzysztof, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Network models are an essential block of modern networks. For example, they are widely used in network planning and optimization. However, as networks increase in scale and complexity, some models present limitations, such as the assumption of Markovian traffic in queuing theory models, or the high computational cost of network simulators. Recent advances in machine learning, such as Graph Neural Networks (GNN), are enabling a new generation of network models that are data-driven and can learn complex non-linear behaviors. In this paper, we present RouteNet-Fermi, a custom GNN model that shares the same goals as Queuing Theory, while being considerably more accurate in the presence of realistic traffic models. The proposed model predicts accurately the delay, jitter, and packet loss of a network. We have tested RouteNet-Fermi in networks of increasing size (up to 300 nodes), including samples with mixed traffic profiles — e.g., with complex non-Markovian models — and arbitrary routing and queue scheduling configurations. Our experimental results show that RouteNet-Fermi achieves similar accuracy as computationally-expensive packet-level simulators and scales accurately to larger networks. Our model produces delay estimates with a mean relative error of 6.24% when applied to a test dataset of 1,000 samples, including network topologies one order of magnitude larger than those seen during training. Finally, we have also evaluated RouteNet-Fermi with measurements from a physical testbed and packet traces from a real-life network., This work was supported in part by the Spanish I+D+i Project TRAINER-A funded by the Ministry of Science and Innovation (MCIN)/State Investigation Agency (AEI)/10.13039/501100011033 under Grant PID2020-118011GB-C21, in part by the Catalan Institution for Research and Advanced Studies (ICREA), and in part by the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2023

35. MAGNNETO: A graph neural network-based multi-agent system for traffic engineering

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Bernárdez Gil, Guillermo, Suárez-Varela Maciá, José Rafael, López Brescó, Albert, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Bernárdez Gil, Guillermo, Suárez-Varela Maciá, José Rafael, López Brescó, Albert, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Current trends in networking propose the use of Machine Learning (ML) for a wide variety of network optimization tasks. As such, many efforts have been made to produce ML-based solutions for Traffic Engineering (TE), which is a fundamental problem in Internet Service Provider (ISP) networks. Nowadays, state-of-the-art TE optimizers rely on traditional optimization techniques, such as Local search, Constraint Programming, or Linear programming. In this paper, we present MAGNNETO, a distributed ML-based framework that leverages Multi-Agent Reinforcement Learning and Graph Neural Networks for distributed TE optimization. MAGNNETO deploys a set of agents across the network that learn and communicate in a distributed fashion via message exchanges between neighboring agents. Particularly, we apply this framework to optimize link weights in Open Shortest Path First (OSPF), with the goal of minimizing network congestion. In our evaluation, we compare MAGNNETO against several state-of-the-art TE optimizers in more than 75 topologies (up to 153 nodes and 354 links), including realistic traffic loads. Our experimental results show that, thanks to its distributed nature, MAGNNETO achieves comparable performance to state-of-the-art TE optimizers with significantly lower execution times. Moreover, our ML-based solution demonstrates a strong generalization capability to successfully operate in new networks unseen during training., This publication is part of the Spanish I+D+i project TRAINER-A (ref. PID2020-118011GBC21), funded by MCIN/AEI/10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA), the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia, and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2023

36. Neural Quantile Optimization for Edge-Cloud Computing

Author

Du, Bin, Zhang, He, Cheng, Xiangle, Zhang, Lei, Du, Bin, Zhang, He, Cheng, Xiangle, and Zhang, Lei

Abstract

We seek the best traffic allocation scheme for the edge-cloud computing network that satisfies constraints and minimizes the cost based on burstable billing. First, for a fixed network topology, we formulate a family of integer programming problems with random parameters describing the various traffic demands. Then, to overcome the difficulty caused by the discrete feature of the problem, we generalize the Gumbel-softmax reparameterization method to induce an unconstrained continuous optimization problem as a regularized continuation of the discrete problem. Finally, we introduce the Gumbel-softmax sampling network to solve the optimization problems via unsupervised learning. The network structure reflects the edge-cloud computing topology and is trained to minimize the expectation of the cost function for unconstrained continuous optimization problems. The trained network works as an efficient traffic allocation scheme sampler, remarkably outperforming the random strategy in feasibility and cost function value. Besides testing the quality of the output allocation scheme, we examine the generalization property of the network by increasing the time steps and the number of users. We also feed the solution to existing integer optimization solvers as initial conditions and verify the warm-starts can accelerate the short-time iteration process. The framework is general with solid performance, and the decoupled feature of the random neural networks is adequate for practical implementations.

Published

2023

37. MAGNNETO: A Graph Neural Network-Based Multi-Agent System for Traffic Engineering

Author

Bernárdez, Guillermo, primary, Suárez-Varela, José, additional, López, Albert, additional, Shi, Xiang, additional, Xiao, Shihan, additional, Cheng, Xiangle, additional, Barlet-Ros, Pere, additional, and Cabellos-Aparicio, Albert, additional

Published

2023

38. Neural Quantile Optimization for Edge-Cloud Computing

Author

Du, Bin, primary, Zhang, He, additional, Cheng, Xiangle, additional, and Zhang, Lei, additional

Published

2023

39. RouteNet-Fermi: Network Modeling With Graph Neural Networks

Author

Ferriol-Galmés, Miquel, primary, Paillisse, Jordi, additional, Suárez-Varela, José, additional, Rusek, Krzysztof, additional, Xiao, Shihan, additional, Shi, Xiang, additional, Cheng, Xiangle, additional, Barlet-Ros, Pere, additional, and Cabellos-Aparicio, Albert, additional

Published

2023

40. Network Digital Twin: Context, Enabling Technologies, and Opportunities

Author

Almasan, Paul, primary, Ferriol-Galmes, Miquel, additional, Paillisse, Jordi, additional, Suarez-Varela, Jose, additional, Perino, Diego, additional, Lopez, Diego, additional, Perales, Antonio Agustin Pastor, additional, Harvey, Paul, additional, Ciavaglia, Laurent, additional, Wong, Leon, additional, Ram, Vishnu, additional, Xiao, Shihan, additional, Shi, Xiang, additional, Cheng, Xiangle, additional, Cabellos-Aparicio, Albert, additional, and Barlet-Ros, Pere, additional

Published

2022

41. Convergence Analysis of Discrete High-Index Saddle Dynamics

Author

Luo, Yue, primary, Zheng, Xiangcheng, additional, Cheng, Xiangle, additional, and Zhang, Lei, additional

Published

2022

42. FlowDT: A Flow-Aware Digital Twin for Computer Networks

Author

Ferriol-Galmes, Miquel, primary, Cheng, Xiangle, additional, Shi, Xiang, additional, Xiao, Shihan, additional, Barlet-Ros, Pere, additional, and Cabellos-Aparicio, Albert, additional

Published

2022

43. RouteNet-Erlang: A Graph Neural Network for Network Performance Evaluation

Author

Ferriol-Galmes, Miquel, primary, Rusek, Krzysztof, additional, Suarez-Varela, Jose, additional, Xiao, Shihan, additional, Shi, Xiang, additional, Cheng, Xiangle, additional, Wu, Bo, additional, Barlet-Ros, Pere, additional, and Cabellos-Aparicio, Albert, additional

Published

2022

44. Network digital twin: context, enabling technologies, and opportunities

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Paillissé Vilanova, Jordi, Suárez-Varela Maciá, José Rafael, Perino, Diego, Lopez, Diego, Pastor Perales, Antonio Agustín, Harvey, Paul, Ciavaglia, Laurent, Wong, Leon, Xiao, Shihan, Ram, Vishnu, Shi, Xiang, Cheng, Xiangle, Cabellos Aparicio, Alberto, Barlet Ros, Pere, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Almasan Puscas, Felician Paul, Ferriol Galmés, Miquel, Paillissé Vilanova, Jordi, Suárez-Varela Maciá, José Rafael, Perino, Diego, Lopez, Diego, Pastor Perales, Antonio Agustín, Harvey, Paul, Ciavaglia, Laurent, Wong, Leon, Xiao, Shihan, Ram, Vishnu, Shi, Xiang, Cheng, Xiangle, Cabellos Aparicio, Alberto, and Barlet Ros, Pere

Abstract

The proliferation of emergent network applications (e.g., telesurgery, metaverse) is increasing the difficulty of managing modern communication networks. These applications entail stringent network requirements (e.g., ultra-low deterministic latency), which hinders network operators to manage their resources efficiently. In this article, we introduce the network digital twin (NDT), a renovated concept of classical network modeling tools whose goal is to build accurate data-driven network models that can operate in real-time. We describe the general architecture of the NDT and argue that modern machine learning (ML) technologies enable building some of its core components. Then, we present a case study that leverages a ML-based NDT for network performance evaluation and apply it to routing optimization in a QoS-aware use case. Lastly, we describe some key open challenges and research opportunities yet to be explored to achieve effective deployment of NDTs in real-world networks., This publication is part of the Spanish I+D+i project TRAINER-A (ref.PID2020- 118011GB-C21), funded by MCIN/ AEI/10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA) and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2022

45. Building a Digital Twin for network optimization using graph neural networks

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Ferriol Galmés, Miquel, Suárez-Varela Maciá, José Rafael, Paillissé Vilanova, Jordi, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Ferriol Galmés, Miquel, Suárez-Varela Maciá, José Rafael, Paillissé Vilanova, Jordi, Shi, Xiang, Xiao, Shihan, Cheng, Xiangle, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Network modeling is a critical component of Quality of Service (QoS) optimization. Current networks implement Service Level Agreements (SLA) by careful configuration of both routing and queue scheduling policies. However, existing modeling techniques are not able to produce accurate estimates of relevant SLA metrics, such as delay or jitter, in networks with complex QoS-aware queueing policies (e.g., strict priority, Weighted Fair Queueing, Deficit Round Robin). Recently, Graph Neural Networks (GNNs) have become a powerful tool to model networks since they are specifically designed to work with graph-structured data. In this paper, we propose a GNN-based network model able to understand the complex relationship between the queueing policy (scheduling algorithm and queue sizes), the network topology, the routing configuration, and the input traffic matrix. We call our model TwinNet, a Digital Twin that can accurately estimate relevant SLA metrics for network optimization. TwinNet can generalize to its input parameters, operating successfully in topologies, routing, and queueing configurations never seen during training. We evaluate TwinNet over a wide variety of scenarios with synthetic traffic and validate it with real traffic traces. Our results show that TwinNet can provide accurate estimates of end-to-end path delays in 106 unseen real-world topologies, under different queuing configurations with a Mean Absolute Percentage Error (MAPE) of 3.8%, as well as a MAPE of 6.3% error when evaluated with a real testbed. We also showcase the potential of the proposed model for SLA-driven network optimization and what-if analysis., This publication is part of the Spanish I+D+i project TRAINER-A (ref.PID2020-118011GB-C21), funded by MCIN/ AEI/, Spain10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA), Spain and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia, Spain and the European Social Fund., Peer Reviewed, Postprint (published version)

Published

2022

46. FlowDT: A Flow-aware Digital Twin for computer networks

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Ferriol Galmés, Miquel, Cheng, Xiangle, Shi, Xiang, Xiao, Shihan, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Ferriol Galmés, Miquel, Cheng, Xiangle, Shi, Xiang, Xiao, Shihan, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Network modeling is an essential tool for network planning and management. It allows network administrators to explore the performance of new protocols, mechanisms, or optimal configurations without the need for testing them in real production networks. Recently, Graph Neural Networks (GNNs) have emerged as a practical solution to produce network models that can learn and extract complex patterns from real data without making any assumptions. However, state-of-the-art GNN-based network models only work with traffic matrices, this is a very coarse and simplified representation of network traffic. Although this assumption has shown to work well in certain use-cases, it is a limiting factor because, in practice, networks operate with flows. In this paper, we present FlowDT a new DL-based solution designed to model computer networks at the fine-grained flow level. In our evaluation, we show how FlowDT can accurately predict relevant per-flow performance metrics with an error of 3.5%, FlowDT’s performance is also benchmarked against vanilla DL models as well as with Queuing Theory., This work has been supported by the Spanish Government through project TRAINER-A (PID2020-118011GB-C21) with FEDER contribution and the Catalan Institution for Research and Advanced Studies (ICREA)., Peer Reviewed, Postprint (author's final draft)

Published

2022

47. RouteNet-Erlang: A graph neural network for network performance evaluation

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Ferriol Galmés, Miquel, Rusek, Krzysztof, Suárez-Varela Maciá, José Rafael, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Wu, Bo, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Ferriol Galmés, Miquel, Rusek, Krzysztof, Suárez-Varela Maciá, José Rafael, Xiao, Shihan, Shi, Xiang, Cheng, Xiangle, Wu, Bo, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Network modeling is a fundamental tool in network research, design, and operation. Arguably the most popular method for modeling is Queuing Theory (QT). Its main limitation is that it imposes strong assumptions on the packet arrival process, which typically do not hold in real networks. In the field of Deep Learning, Graph Neural Networks (GNN) have emerged as a new technique to build data-driven models that can learn complex and non-linear behavior. In this paper, we present RouteNet-Erlang, a pioneering GNN architecture designed to model computer networks. RouteNet-Erlang supports complex traffic models, multi-queue scheduling policies, routing policies and can provide accurate estimates in networks not seen in the training phase. We benchmark RouteNet-Erlang against a state-of-the-art QT model, and our results show that it outperforms QT in all the network scenarios., This publication is part of the Spanish I+D+i project TRAINER-A (ref.PID2020-118011GB-C21), funded by MCIN/ AEI/10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA) and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2022

48. ENERO: Efficient real-time WAN routing optimization with Deep Reinforcement Learning

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Almasan Puscas, Felician Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Almasan Puscas, Felician Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

Wide Area Networks (WAN) are a key infrastructure in today’s society. During the last years, WANs have seen a considerable increase in network’s traffic and network applications, imposing new requirements on existing network technologies (e.g., low latency and high throughput). Consequently, Internet Service Providers (ISP) are under pressure to ensure the customer’s Quality of Service and fulfill Service Level Agreements. Network operators leverage Traffic Engineering (TE) techniques to efficiently manage the network’s resources. However, WAN’s traffic can drastically change during time and the connectivity can be affected due to external factors (e.g., link failures). Therefore, TE solutions must be able to adapt to dynamic scenarios in real-time. In this paper we propose Enero, an efficient real-time TE solution based on a two-stage optimization process. In the first one, Enero leverages Deep Reinforcement Learning (DRL) to optimize the routing configuration by generating a long-term TE strategy. To enable efficient operation over dynamic network scenarios (e.g., when link failures occur), we integrated a Graph Neural Network into the DRL agent. In the second stage, Enero uses a Local Search algorithm to improve DRL’s solution without adding computational overhead to the optimization process. The experimental results indicate that Enero is able to operate in real-world dynamic network topologies in 4.5 s on average for topologies up to 100 links., This publication is part of the Spanish I+D+i project TRAINER-A (ref.PID2020-118011GB-C21), funded by MCIN/ AEI/ 10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA) and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (published version)

Published

2022

49. Accelerating deep reinforcement learning for digital twin network optimization with evolutionary strategies

Author

Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Güemes Palau, Carlos, Almasan Puscas, Felician Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet Ros, Pere, Cabellos Aparicio, Alberto, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Güemes Palau, Carlos, Almasan Puscas, Felician Paul, Xiao, Shihan, Cheng, Xiangle, Shi, Xiang, Barlet Ros, Pere, and Cabellos Aparicio, Alberto

Abstract

The recent growth of emergent network applications (e.g., satellite networks, vehicular networks) is increasing the complexity of managing modern communication networks. As a result, the community proposed the Digital Twin Networks (DTN) as a key enabler of efficient network management. Network operators can leverage the DTN to perform different optimization tasks (e.g., Traffic Engineering, Network Planning).Deep Reinforcement Learning (DRL) showed a high performance when applied to solve network optimization problems. In the context of DTN, DRL can be leveraged to solve optimization problems without directly impacting the real-world network behavior. However, DRL scales poorly with the problem size and complexity. In this paper, we explore the use of Evolutionary Strategies (ES) to train DRL agents for solving a routing optimization problem. The experimental results show that ES achieved a training time speed-up of 128 and 6 for the NSFNET and GEANT2 topologies respectively., This publication is part of the Spanish I+D+i project TRAINER-A (ref.PID2020-118011GB-C21), funded by MCIN/ AEI/10.13039/501100011033. This work is also partially funded by the Catalan Institution for Research and Advanced Studies (ICREA) and the Secretariat for Universities and Research of the Ministry of Business and Knowledge of the Government of Catalonia and the European Social Fund., Peer Reviewed, Postprint (author's final draft)

Published

2022

50. Accelerating Deep Reinforcement Learning for Digital Twin Network Optimization with Evolutionary Strategies

Author

Guemes-Palau, Carlos, primary, Almasan, Paul, additional, Xiao, Shihan, additional, Cheng, Xiangle, additional, Shi, Xiang, additional, Barlet-Ros, Pere, additional, and Cabellos-Aparicio, Albert, additional

Published

2022