dReDBox: Materializing a full-stack rack-scale system prototype of a next-generation disaggregated datacenter

Current datacenters are based on server machines, whose mainboard and hardware components form the baseline, monolithic building block that the rest of the system software, middleware and application stack are built upon. This leads to the following limitations: (a) resource proportionality of a multi-tray system is bounded by the basic building block (mainboard), (b) resource allocation to processes or virtual machines (VMs) is bounded by the available resources within the boundary of the mainboard, leading to spare resource fragmentation and inefficiencies, and (c) upgrades must be applied to each and every server even when only a specific component needs to be upgraded. The dRedBox project (Disaggregated Recursive Datacentre-in-a-Box) addresses the above limitations, and proposes the next generation, low-power, across form-factor datacenters, departing from the paradigm of the mainboard-as-a-unit and enabling the creation of function-block-as-a-unit. Hardware-level disaggregation and software-defined wiring of resources is supported by a full-fledged Type-1 hypervisor that can execute commodity virtual machines, which communicate over a low-latency and high-throughput software-defined optical network. To evaluate its novel approach, dRedBox will demonstrate application execution in the domains of network functions virtualization, infrastructure analytics, and real-time video surveillance.This work has been supported in part by EU H2020 ICTproject dRedBox, contract #687632.Peer ReviewedPostprint (author's final draft

Käyttäjätason ohjelmistokontittaminen pilviradioliityntäverkossa

The amount of devices connected through mobile networks has been growing rapidly. This growth will create a demand for network capacity that cannot be met with traditional methods. This problem could be solved by implementing a cloud radio access network (RAN), a new concept, to adapt cloud computing technologies, such as software containers, from the software industry to RANs. This adaptation will also create a need to modify working practices in order to better comply with these new cloud computing technologies. While cloud RAN has recently received much research attention, the actual software implementations have not been widely discussed in the literature. Therefore, this thesis evaluates the feasibility of using software containers in the user-plane applications of cloud RAN in terms of networking and inter-container communications (ICC). This is accomplished by identifying potential approaches for ICC and for container networking as well as measuring the performance of these approaches. Two approaches are proposed for ICC and container networking. The approaches were evaluated in terms of throughput and latency. These approaches were found to be suitable for use in cloud RAN user-plane applications. However, since the measurements were performed in a simplified environment, implementing the approaches into a cloud RAN component will require further work.Mobiiliverkkoihin liitettävien laitteiden määrä kasvaa nopeasti. Tämä kasvu tulee luomaan verkon kapasiteetille kysynnän, johon ei kyetä vastaamaan perinteisin menetelmin. Tämä ongelma voitaineen ratkaista implementoimalla pilviradioliityntäverkko (Cloud RAN), uusi konsepti, joka sovittaa ohjelmistoalalla vakiintuneita pilvilaskentateknologioita käytettäväksi radioliityntäverkoissa (radio access network, RAN). Tämä sovitusprosessi luo tarpeen mukauttaa myös työskentelytavat yhteensopiviksi uusien pilvilaskentateknologioiden kanssa. Vaikka pilviradioliityntäverkkoa on tutkittu aktiivisesti viime aikoina, käytännön ohjelmistototeutukset eivät juuri ole olleet esillä kirjallisuudessa. Tämä diplomityö arvioi ohjelmistokonttien (software containers) soveltuvuutta käytettäväksi pilviradioliityntäverkon käyttäjätason (user-plane) applikaatioissa verkottamisen (networking) ja ohjelmistokonttien välisen kommunikoinnin (inter-container communications, ICC) suhteen. Tämä arviointi suoritetaan identifioimalla mahdollisia toteutuksia ohjelmistokonttien väliselle kommunikaatiolle ja ohjelmistokonttien verkottamiselle sekä mittaamalla näiden toteutuksien suorituskyky. Tässä diplomityössä ehdotetaan tutkittavaksi kaksi toteutusta ohjelmistokonttien väliselle kommunikaatiolle ja ohjelmistokonttien verkottamiselle. Nämä toteutukset arvioitiin välityskyvyn (throughput) ja latenssin suhteen. Näiden toteutuksien todettiin olevan soveliaita käytettäväksi pilviradioliityntäverkon käyttäjätason applikaatioissa. Kuitenkin, koska mittaukset toteutettiin yksinkertaistetussa ympäristössä, vaatii toteutuksien implementointi pilviradioliityntäverkon komponenttiin lisätyötä

NeutRAN: An Open RAN Neutral Host Architecture for Zero-Touch RAN and Spectrum Sharing

Obtaining access to exclusive spectrum, cell sites, Radio Access Network (RAN) equipment, and edge infrastructure imposes major capital expenses to mobile network operators. A neutral host infrastructure, by which a third-party company provides RAN services to mobile operators through network virtualization and slicing techniques, is seen as a promising solution to decrease these costs. Currently, however, neutral host providers lack automated and virtualized pipelines for onboarding new tenants and to provide elastic and on-demand allocation of resources matching operators' requirements. To address this gap, this paper presents NeutRAN, a zero-touch framework based on the O-RAN architecture to support applications on neutral hosts and automatic operator onboarding. NeutRAN builds upon two key components: (i) an optimization engine to guarantee coverage and to meet quality of service requirements while accounting for the limited amount of shared spectrum and RAN nodes, and (ii) a fully virtualized and automated infrastructure that converts the output of the optimization engine into deployable micro-services to be executed at RAN nodes and cell sites. NeutRAN was prototyped on an OpenShift cluster and on a programmable testbed with 4 base stations and 10 users from 3 different tenants. We evaluate its benefits, comparing it to a traditional license-based RAN where each tenant has dedicated physical and spectrum resources. We show that NeutRAN can deploy a fully operational neutral host-based cellular network in around 10 seconds. Experimental results show that it increases the cumulative network throughput by 2.18x and the per-user average throughput by 1.73x in networks with shared spectrum blocks of 30 MHz. NeutRAN provides a 1.77x cumulative throughput gain even when it can only operate on a shared spectrum block of 10 MHz (one third of the spectrum used in license-based RANs).Comment: 13 pages, 11 figures, 1 table. IEEE Transactions on Mobile Computing, August 202