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A Latency-Driven Availability Assessment for Multi-Tenant Service Chains

Luigi De Simone, Mario Di Mauro, Roberto Natella, F. Postiglione

2022IEEE Transactions on Services Computing26 citationsDOIOpen Access PDF

Abstract

Nowadays, most telecommunication services adhere to the Service Function Chain (SFC) paradigm, where network functions are implemented via software. In particular, container virtualization is becoming a popular approach to deploy network functions and to enable resource slicing among several tenants. The resulting infrastructure is a complex system composed by a huge amount of containers implementing different SFC functionalities, along with different tenants sharing the same chain. The complexity of such a scenario lead us to evaluate two critical metrics: the steady-state availability (the probability that a system is functioning in long runs) and the latency (the time between a service request and the pertinent response). Consequently, we propose a latency-driven availability assessment for multi-tenant service chains implemented via Containerized Network Functions (CNFs). We adopt a multi-state system to model single CNFs and the queueing formalism to characterize the service latency. To efficiently compute the availability, we develop a modified version of the Multidimensional Universal Generating Function (MUGF) technique. Finally, we solve an optimization problem to minimize the SFC cost under an availability constraint. As a relevant example of SFC, we consider a containerized version of IP Multimedia Subsystem, whose parameters have been estimated through fault injection techniques and load tests.

Topics & Concepts

Computer scienceDistributed computingLatency (audio)SlicingNetwork Functions VirtualizationNetwork serviceQueueing theoryFault toleranceService (business)Virtual networkComputer networkCloud computingOperating systemEconomicsEconomyWorld Wide WebTelecommunicationsSoftware-Defined Networks and 5GSoftware System Performance and ReliabilityCloud Computing and Resource Management