Next-Generation Self-Organizing Networks through a Machine Learning Approach

Fecha de lectura de Tesis Doctoral: 17 Diciembre 2018.Para reducir los costes de gestión de las redes celulares, que, con el tiempo, aumentaban en complejidad, surgió el concepto de las redes autoorganizadas, o self-organizing networks (SON). Es decir, la automatización de las tareas de gestión de una red celular para disminuir los costes de infraestructura (CAPEX) y de operación (OPEX). Las tareas de las SON se dividen en tres categorías: autoconfiguración, autooptimización y autocuración. El objetivo de esta tesis es la mejora de las funciones SON a través del desarrollo y uso de herramientas de aprendizaje automático (machine learning, ML) para la gestión de la red. Por un lado, se aborda la autocuración a través de la propuesta de una novedosa herramienta para una diagnosis automática (RCA), consistente en la combinación de múltiples sistemas RCA independientes para el desarrollo de un sistema compuesto de RCA mejorado. A su vez, para aumentar la precisión de las herramientas de RCA mientras se reducen tanto el CAPEX como el OPEX, en esta tesis se proponen y evalúan herramientas de ML de reducción de dimensionalidad en combinación con herramientas de RCA. Por otro lado, en esta tesis se estudian las funcionalidades multienlace dentro de la autooptimización y se proponen técnicas para su gestión automática. En el campo de las comunicaciones mejoradas de banda ancha, se propone una herramienta para la gestión de portadoras radio, que permite la implementación de políticas del operador, mientras que, en el campo de las comunicaciones vehiculares de baja latencia, se propone un mecanismo multicamino para la redirección del tráfico a través de múltiples interfaces radio. Muchos de los métodos propuestos en esta tesis se han evaluado usando datos provenientes de redes celulares reales, lo que ha permitido demostrar su validez en entornos realistas, así como su capacidad para ser desplegados en redes móviles actuales y futuras

Cell fault management using machine learning techniques

This paper surveys the literature relating to the application of machine learning to fault management in cellular networks from an operational perspective. We summarise the main issues as 5G networks evolve, and their implications for fault management. We describe the relevant machine learning techniques through to deep learning, and survey the progress which has been made in their application, based on the building blocks of a typical fault management system. We review recent work to develop the abilities of deep learning systems to explain and justify their recommendations to network operators. We discuss forthcoming changes in network architecture which are likely to impact fault management and offer a vision of how fault management systems can exploit deep learning in the future. We identify a series of research topics for further study in order to achieve this

Methods for Self-Healing based on traces and unsupervised learning in Self-Organizing Networks

With the advent of Long-Term Evolution (LTE) networks and the spread of a highly varied range of services, mobile operators are increasingly aware of the need to strengthen their maintenance and operational tasks in order to ensure a quality and positive user experience. Furthermore, the co- existence of multiple Radio Access Technologies (RAT), the increase in the traffic demand and the need to provide a great variety of services are steering the cellular network toward a new scenario where management tasks are becoming increasingly complex. As a result, mobile operators are focusing their efforts to deal with the maintenance of their networks without increasing either operational expenditures (OPEX) or capital expenditures (CAPEX). In this context, it is becoming necessary to effectively automate the management tasks through the concept of the Self-Organizing Networks (SON). In particular, SON functions cover three different areas: Self-Configuration, Self-Optimization and Self- Healing. Self-Configuration automates the deployment of new network elements and their parameter configuration. Self-Optimization is in charge of modifying the configuration of the parameters in order to enhance user experience. Finally, Self-Healing aims reduce the impact that failures and services degradation have on the end-user. To that end, Self-Healing (SH) systems monitor the network elements through several alarms, measurements and indicators in order to detect outage and degraded cells, then, diagnose the cause of their problem and, finally, execute the compensation or recovery actions. Even though mobile networks are become more prone to failures due to their huge increase in complexity, the automation of the troubleshooting tasks through the SH functionality has not been fully realized. Traditionally, both the research and the development of SON networks have been related to Self-Configuration and Self-Optimization. This has been mainly due to the challenges that need to be faced when SH systems are studied and implemented. This is especially relevant in the case of fault diagnosis. However, mobile operators are paying increasingly more attention to self-healing systems, which entails creating options to face those challenges that allow the development of SH functions. On the one hand, currently, the diagnosis continues to be manually done since it requires considerable hard-earned experience in order to be able to effectively identify the fault cause. In particular, troubleshooting experts thoroughly analyze the performance of the degraded network elements by means of measurements and indicators in order to identify the cause of the detected anomalies and symptoms. Therefore, automating the diagnosis tasks means knowing what specific performance indicators have to be analyzed and how to map the identified symptoms with the associate fault cause. This knowledge is acquired over time and it is characterized by being operator-specific based on their policies and network features. Furthermore, troubleshooting experts typically solve the failures in a network without either documenting the troubleshooting process or recording the analyzed indicators along with the label of the identified fault cause. In addition, because there is no specific regulation on documentation, the few documented faults are neither properly defined nor described in a standard way (e.g. the same fault cause may be appointed with different labels), making it even more difficult to automate the extraction of the expert knowledge. As a result, this a lack of documentation and lack of historical reported faults makes automation of diagnosis process more challenging. On the other hand, when the exact root cause cannot be remotely identified through the statistical information gathered at cell level, drive test are scheduled for further information. These drive tests aim to monitor mobile network performance by using vehicles to personally measure the radio interface quality along a predefined route. In particular, the troubleshooting experts use specialized test equipment in order to manually collect user-level measurements. Consequently, drive test entail a hefty expense for mobile operators, since it involves considerable investment in time and costly resources (such as personal, vehicles and complex test equipment). In this context, the Third Generation Partnership Project (3GPP) has standardized the automatic collection of field measurements (e.g. signaling messages, radio measurements and location information) through the mobile traces features and its extended functionality, the Minimization of Drive Tests (MDT). In particular, those features allow to automatically monitor the network performance in detail, reaching areas that cannot be covered by drive testing (e.g. indoor or private zones). Thus, mobile traces are regarded as an important enabler for SON since they avoid operators to rely on those expensive drive tests while, at the same time, provide greater details than the traditional cell-level indicators. As a result, enhancing the SH functionalities through the mobile traces increases the potential cost savings and the granularity of the analysis. Hence, in this thesis, several solutions are proposed to overcome the limitations that prevent the development of SH with special emphasis on the diagnosis phase. To that end, the lack of historical labeled databases has been addressed in two main ways. First, unsupervised techniques have been used to automatically design diagnosis system from real data without requiring either documentation or historical reports about fault cases. Second, a group of significant faults have been modeled and implemented in a dynamic system level simulator in order to generate an artificial labeled database, which is extremely important in evaluating and comparing the proposed solutions with the state-of- the-art algorithm. Then, the diagnosis of those faults that cannot be identified through the statistical performance indicators gathered at cell level is automated by the analysis of the mobile traces avoiding the costly drive test. In particular, in this thesis, the mobile traces have been used to automatically identify the cause of each unexpected user disconnection, to geo-localize RF problems that affect the cell performance and to identify the impact of a fault depending on the availability of legacy systems (e.g. Third Generation, 3G). Finally, the proposed techniques have been validated using real and simulated LTE data by analyzing its performance and comparing it with reference mechanisms

Cognition-Based Networks: A New Perspective on Network Optimization Using Learning and Distributed Intelligence

IEEE Access Volume 3, 2015, Article number 7217798, Pages 1512-1530 Open Access Cognition-based networks: A new perspective on network optimization using learning and distributed intelligence (Article) Zorzi, M.a , Zanella, A.a, Testolin, A.b, De Filippo De Grazia, M.b, Zorzi, M.bc a Department of Information Engineering, University of Padua, Padua, Italy b Department of General Psychology, University of Padua, Padua, Italy c IRCCS San Camillo Foundation, Venice-Lido, Italy View additional affiliations View references (107) Abstract In response to the new challenges in the design and operation of communication networks, and taking inspiration from how living beings deal with complexity and scalability, in this paper we introduce an innovative system concept called COgnition-BAsed NETworkS (COBANETS). The proposed approach develops around the systematic application of advanced machine learning techniques and, in particular, unsupervised deep learning and probabilistic generative models for system-wide learning, modeling, optimization, and data representation. Moreover, in COBANETS, we propose to combine this learning architecture with the emerging network virtualization paradigms, which make it possible to actuate automatic optimization and reconfiguration strategies at the system level, thus fully unleashing the potential of the learning approach. Compared with the past and current research efforts in this area, the technical approach outlined in this paper is deeply interdisciplinary and more comprehensive, calling for the synergic combination of expertise of computer scientists, communications and networking engineers, and cognitive scientists, with the ultimate aim of breaking new ground through a profound rethinking of how the modern understanding of cognition can be used in the management and optimization of telecommunication network