1、 EN EN EUROPEAN COMMISSION Brussel������s,21.2.2024 COM(2024)81 final WHITE PAPER How to master Europes digital infrastructure needs?1-White paper “How to master Europes digital infrastruc������ture needs?”1.INTRODUCTION.3 2.TRENDS AND CHALLENGES IN THE DIGITAL INFRASTRUCTURE SECTOR.5 2.1.Europes connectivity i
2、nfrastructure challenges.5 2.2.Te��������chnological challenges.7 2.3.Challenges of achieving scale in EU connectivity services.10 2.3.1.Investment needs.10 2.3.2.Financial situation of the EU electronic communications sector.10 2.3.3.Lack of������ single market.12 2.3.4.Convergence and level playing field.15 2.3
3、.5.Sustainability challenges.16 2.4.Need for security in the supply and in the operation of networks.17 2.4.1.Challenge of trusted suppliers.17 2.4.2.Security standards for end-to-end connectivity.17 2.4.3.Secure and resilient submarine cable infrastructure������s.18 3.MASTERING THE TRANSITION TO THE DIGI
4、TAL NETWORKS OF THE FUTURE-POLICY ISSUES AND POSSIBLE SOLUTIONS.20 3.1.Pillar I:Creating the“3C Network”-“Connected Collaborative Computing”.20 3.1.1.Capacity building through open innovation���� and technology capabilities.20 3.1.2.Way forward.22 3.1.3.Summary of possible scenarios.24 3.2.Pillar II:Com
5、pleting the Digital Single Market.25 3.2.1.Objectives.25 3.2.2.Scope of application.25 3.2.3.Authorisation.26 3.2.4.Addressing barriers to core network centralisation.27 3.2.5.Radio spectrum.28 3.2.6.Copper switch-off.31 3.2.7.Access policy in a full fibre environment.32 3�����.2.8.Universal service and
6、affordability of digital infrastructure.34 3.2.9.Sustainabili�������ty.35 3.2.10.Summary of possible scenarios.36 2 3.3.Pillar III:Secure and resilient digital infrastructures for Europe.37 3.3.1.Towards s�����ecure communication using quantum and post-quantum technologies.37 3.3.2.Towards security and resilien
7、ce of submarine cable infrastructures.38 3.3.3.Summary of possible scenarios .40 4.CONCLUSION.40 3 1.INTRODUCTION A cutting-edge digital network infrastructure is the foundation ��������for a flourishing digital economy and soci����ety.Secure and sustainable digital infrastructures are one of the four cardinal
8、points of the EUs Digital Decade Policy Programme 2030,one of the main priorities of the current Commission.It is also at the heart of citizens interest,who made several digital-relat�������ed proposals in the context of the Conference on the Future of Europe.Without advanced digital network infrastructure
9、s,applications will not make our lives easier,and consumers will be deprived of the benefits of advanced technologi�����es.Only with the highest performance of such infrastruc�������tures,for example,will doctors be able to care for patients at a distance rapidly and safely,drones be able to improve harvests an
10、d reduce water and pesticide use,while connected temperature and humidity sensors enable real-time monitoring of the conditions in which fresh food is stored and transported to the consumer.There are also many examples across the economy of how enterprises need advance�������d c�����onnectivity and computing in
11、frastructures for the processing of data closer t�����o their operations and to their customers,to use or provide innovative applications and services.This is especially important for applications tha�������t require real-time data processing,such as Internet of Things(IoT)devices,autonomous vehicles,and smart
12、grids,as well as to reduce latency for applications related to predictive maintenance,real-time monitoring,and automation,leading to more efficient and cost-effective operations.Ad�������vanced digital network infrastructures and services will become a key enabler for transformative digital technologies an
13、d services such as Artificial Intelligence(AI),Virtual Worlds and the Web 4.0,and for addressing societal challenges such as those in the fields of energy,transport or healthcare and for supporting inno����vation in creative industries.The future competitiveness of all sectors of Europes economy depends
14、 on these advanced digital network infrastructures and services,as they form the basis for global GDP growth between EUR 1 and 2 trillion1 and the digital and green transition of our society ������and economy.There is,according to many sources,a strong link between the increased deployment of ����fixed and mo
15、bile broadband and economic development2.Demand for connectivity is essential to stimulate the economy.Higher speeds and new generations of mobile networks have a positive impact on GDP3.S������imilarly,studies show that a resilient backbone infrastructure based on secure submarine cables can boost GDP4.W
16、ith the current demographic trends,European 1 Connected World:An evolution in connectivity beyond the 5G evolution,McKinsey 2020 available at htt������ps:/ 2 Cf.“Analyzing the Economic Impacts of������� Telecommunications”Exploring the Relationship Between Broadband and Economic Growth”,Background Paper prepared
17、 for the World Development Report 2016:Digital Dividends,Michael Minges,2015;“Europes internet ecosystem:socio-economic benefits of a fairer balance between tech giants and telecom operators”,Axon Partners Group,May 2022;Kongaut,Chatchai;Bohlin,Erik(2014):Impact of broadband spee������d on economic output
18、s:An empirical study of OECD countries,25th European Regional Conference of the International Telecommunications Society(ITS):Disrup����tive Innovation in the ICT Industries:Challenges for European Policy and Business,Brussels,Belgium,22nd-25th June,2014,In������ternational Telecommunications Society(ITS),Cal
19、gary.3 Specifically,mobiles baseline connectivity impact increases by about 15%when connecti�����ons are upgraded to 3G.For c�������onnections upgrading from 2G to 4G,the impact increases by approximately 25%,according to Mobile technology:two decades driving economic growth()4 https:/ competitiveness needs to
20、rely on productivity-boosting technologies,and digital infrastructure and services are key.In parallel,digital networks are undergoi������ng a transformation where connectivity infrastructure is converging with cloud and edge computing capabilitie������s.To harness the benefits of this transformation,the electr
21、onic c��ommunications se�������ctor needs to expand from the traditional consumer internet market towards digital services in key economic sectors,such as the Industrial Internet of Things(IIoT).Moreover,the equipment sector also faces major technological transformations linked to the trend towards software
22、and cloud-based networks and open architectures.Convergence of the������ electronic communications and IT ecosystems brings opportunities for lower cost and innovative services,but also new risks of bottlenecks and dependencies in the field of cloud infrastructure and services as well as leading chip plat
23、forms5.To ensure economic������ security,it is therefore of utmost importance that innovation in this field continues to be driven in the Union and led by its industry.To achieve this,in the current geopolitical context,the Union needs to leverage its current strength in the network equipment supply marke
24、t,with two of the three global suppliers being European���.From a societal perspective,the availability of high-quality,reliable and secure connectivity for everybody and everywhere in the Union,including in rural and remote areas,is indispensable6.The necessary investments are massive7.A modern regula
25、tory framework that incentivises the transition from lega��������cy copper networks to fibre networks,the development of 5G and other wireless networks and cloud-based infrastructures as well as the scale up of operators within the single market,and which takes account of emerging technologies such as quant
26、um comm������unication,is key to ensuring that Europe has the advanced,secured communications and computing infrastructure it needs.Short of that,the EU risks missing its 2030 digital targets and falling behind other leading regions as regards competitiveness and economic������ growth and related user benefits.
27、Finally,recent geopolitical������ developments highlighted the importance of security and resilience of infrastructures against both human-made and natural hazards,as well as the complementary role of terrestrial,satellite and submarine connectivity solutions,for uninterrupted availability of service unde
28、r all ci������rcumstances.In a rapidly changing security landscape,a strategic Union-wide approach to security and resilience of critical digital infrastructures is essential for the EUs economic security,building on the solid existing legislative framework,notably the NIS2 5 Cybersecurity of Open Radio A
29、ccess Networks,Report ��������by NIS Cooperation Group,May 2022.6 This was also acknowledged in the Digital Decade Policy Programme 2030(Decision(EU)2022/2481 of the European Parliament and of the Council of 14 December 2022 establishing the Digital Decade Policy Programme 2030,OJ L 323,19.12.202�������2,p.4.).Acc
30、ording to its Art.4(2)(a),by 2030 all end users at a fixed location should be covered by a gigabit network up to the network termination point,and all populated areas should be covered by next-generation wireless high-speed networks with performance at least equivalent to that of 5G,in ac������c�����ordance wi
31、th the principle of technological neutrality.7 https:/digital-strategy.ec.europa.eu/en/library/investment-and-funding-needs-dig����ita�����l-decade-connectivity-targets.5 Directive8,the Directive on the resilience of critical entities9 and the Council Recommendation on a Union-wide coordinated approach to st
32、rengthen the resilience of critical infrastructure10 11.Against this background,this Wh�������ite Paper identifies challenges and discusses possible scenarios for public policy actions,such as a possible future Digital Networks Act,that aim to incentivise building the digital networks of the future,master
33、the transition to new technologies and business models,meet future connectivity needs of all end-users,underpin competitiveness of our economy and ensure secure and resilient infrastructures and the Unions economic security as������ reflected by the common commitments of the EU Member States in the Digita
34、l Decade Policy Programme12.2.TRENDS AND CHALLENGES IN THE DIGITAL INFRASTRUCTURE SECTOR 2.1.Europes connectivity infrastructure challenges The connectivity infrastructure of the Union is not yet ready to address the current and future challenges of the data-dri�����ven society and economy and the future
35、 needs of all end-users.On the supply side,the 2023 Report on the state of the Digital Decade13 underlines in particular limited fibre coverage(56%of all households,41%of households���� in rural areas)14 and delays in the depl�������oyment of 5G standalone networks in the EU.Current trends concerning the traje
36、ctories for the digital infrastructure targets laid out in the Digital Decade Policy Programme 203015 are a cause for con�����cern.As regards fibre coverage,progress beyond 80%by 2028 does not seem likely,putting the������� achievement of the 2030 target of 100%in doubt.In comparison to the 56%fibre coverage in
37、 the EU in 2022,the US,which has traditionally relied on cable,had 48.8%,while Japan and South Korea each reached 99.7%16,due to clear st���������rategies in favour of f�����ibre.As regards 5G roll-out,while basic 5G population coverage in the EU currently stands at 81%(with only 51%coverage of the population in
38、rural areas),this metric does not reflect the delivery of actual advanced 5G performance.Most often,where 5�����G is deployed,it is not“stand-alone”,i.e.with a core network separate from previous generations.Prospects for deployment of 5G stand-alone networks ensuring high reliability and low latency,whi
39、c�������h are key enablers 8 Directive(EU)2022/2555 of the European Parliament and of the Council of 14 December 2022 on measures for a high common level of cybersecurity across the Union,amending Regulation(EU)No 910/2014 and Directive(EU)2018/1972,and repealing Directive(EU)�����2016/1148(NIS 2 Directive),OJ
40、L 333,27.12.2022,p.80152.9 Directive(EU)2022/2557 of the European Parliament and of the Council of 14 December 2022 on the resilience of critical entities������� and repealing Council Direct�����ive 2008/114/EC,OJ L 333,27.12.2022,p.164198.10 Council Recommendation of 8 December 2022 on a Union-wide coordinated
41、 approach to strengthen the resilience of critical infrastructure,2023/C 20/01,OJ C 20,20.1.2023,p.111.11 This ������approach should also integrate challenges and opportunities for EU enlargement policies.12 Decision(EU)2022/2481 of the European Parliament and of the Council of 14 December 2022 establishi
42、ng the Digital Decade Policy Programme2030,OJ L 323,19.12.2022,p.4.13 https:/digital-strategy.ec.europa.eu/en/library/2023-report-state-digital������-decade.14 https:/digital-strategy.ec.europa.eu/en/library/broadband-coverage-europe-2022.15 The Digital Decade Policy Programme sets a series of objectives
43、and targets to promote the deve������lopment of resilient,secure,performant and sustainable digital infrastructures in the Union,including a digital target for the Commission and Member States to achieve gigabit connectivity for all by 2030.The Programme should enable connectivity across the Uni������on and aro
44、und the globe,for citizens and business,including,but not limited to,providing access to affordable high-speed broadband that can help remove communication dead zones and increase cohe������sion across the Union,including its outermost regions,rural,peripheral,remote and isolated areas and islands.16 See
45、Global Fi�������bre Development Index 2023,Omdia.6 for industrial use cases,are not good.The deployment of such networks can be estimated at significantly less than 20%of populated areas in the EU.Although there is progress on early-stage trials,operator��������s have launched this architecture only in a small num
46、ber of Member States and limited to some urban areas17.Such limited deployment could,among others,be related to the early stage of 3.6 GHz band deployment.Co����verage by 5G in this mid-wave band,that is needed for higher speeds and capacity,currently stands at only 41%of the ����population.5G will need,how
47、ever,to ext������end its footprint beyond populated areas,to cater for advanced services,such as precision farming.Also,while basic 5G coverage in the largest Member States is relatively similar to the US,other regions such as South Korea and China are better prepared for 5G stand-alone deployment.Accordi
48、ng to the 5G Observatorys International S������coreboard,South Korea has deployed more than five times the number of 5G base stations per 100,000 inhabitants than the EU,and China almost triple18.Finally,satellite broadband can bring broadband services with up to 100 Mbps download speeds to very rural and
49、 remote areas,where no very high-capacity networks are available,even if affordability remains crucial to facilitate take-up in these areas.They can also provide r�����esilient eme������rgency services in disaster or crisis situations.However,while satellite services can bridge the digital divide,they cannot c
50、urrently replace the performance of ground-based networks.Overall,and without taking into account population density and quality������� of connectivity,the EU has similar fixed and mobile coverage than the US but lags significantl������y behind other parts of the world in particular on fibre coverage and 5G stan
51、d-alone.However,what counts more is what remains to be covered and more importantly whether the EU is in a go������od position to achieve its Digital Decade objectives for ubiquitous f������ibre and 5G coverage.In this respect,take-up of high-speed services is of paramount importance,as it affects the capacity
52、of the sector to invest.On the demand side,the take-up of at least 1 Gbps broadband is very low(at 14%in 2022 at EU level)and just above half of all EU households(55%)have adopted at l������east 100 Mbps broadband.The take-up of high-speed fixed broadband subscriptions is lower in the EU than the US,South
53、 Korea or Japan19.Standard mobile broadband take-up is better and lies at 87%,despite almost ubiquitous coverage with at least 4G ne������tworks.These delays represent a critical vulnerability for Europes economy as a whole,as the delivery of advanced data services������ and AI-based applications depends on the
54、m.The same applies to the deployment of edge computing infras��������tructure,another key enabler for time critica�������l applications and computing capabilities in relation to real-time data-intensive use cases and IoT.There is a strong correlation between the deployment of capable digital networks and the take-
55、up of modern technologies,which are currently not developing at large scale.The Digital Decade Policy Programme sets������ out a target of 10,000 climate-neutral highly secure edge nodes to be deployed by 2030 as well as targets for adoption of digital technologies,such as cloud,big data and AI,by Europea
56、n companies.The 2023 Report on the state of the Digital Decade underlined the risks for the achievement of these targets.Edge computing is still at its infancy in Europe20.The first data collected by the Edge Observatory21 show that����� Europe is on track in the initial 17 5G Observatory Biannual Report
57、 October 2023,page 8,https:/5gobservatory.eu/wp-content/uploads/2023/12/BR-19_October-2023_Final-clean.pdf 18 5G base stations ������per 100,000 inhabitants:419(South Korea),206(China),77(EU),118(Japan),30(US).19 Cf.International DESI(to be published on the basis of OECD data).24.07 subscriptions per 100
58、inhabitants are higher than 100 Mbps in the EU,comparing to 29.60 in the US,33,36 in Japan and 43,60 in South Korea.20 Report on the state of the Digital Decade 2023,SWD Digital Deca���������de Cardinal Points,section 2.4.21 https:/digital-strategy.ec.europa.eu/en/policies/edge-observatory.7 phase of edge no
59、des deployment.However,under current trends,and without further investment and incentives,the targets are unlikely to be met by 2030.Modern digital������ networks capable of expanding and maturing would stimulate the development of new use cases,creating business opportunities contributing to the digital
60、transformation of Europe.The impact of missing the Digital Decade digital infrastructure targets would be far-rea�����ching,going beyond the scope of the digital sector,and would lead to missed opportunities in innovation areas such as automated driving,sm�������art manufacturing,and personalised health care.2.
61、2.Technological challenges New business models and entirely new markets are emerging from technological developments around the App Economy,IoT,Data Analytics,AI or new forms of content delivery such a�������s high-quality video streaming.These applications require a continuous exponential incre������ase in data
62、 processing,storage,and transmission.The ability to process and transport large amounts of data across the entire global Internet has led to the remote storage and processing of data in the cloud,between the cloud and the end-user through Content Delivery Networks(CDNs),and close to the end-u������ser(edg
63、e computing).This has led to the virtualisation of electronic communications networks functions in software and a shifting of these functions to the cloud o�����r the edge22.This new model of network and service provision rel�����ies not only on traditional electronic communications equipment,network and serv
64、ice providers ������but also on a complex ecosystem of cloud,edge,content,software and component suppliers,amongst others.The traditional boundaries between these various actors are increasingly blurred as they form part of what can be described as a computing continuum:from chips and other components for
65、 high-speed processors embedded in devices,to edge computing working cohesively with centralised cloud services and AI-powered applications managing the network.This will allow �������computing to be integrated everywhere in the network.There is a need to orchestrate these different elements.This coordinat
������66、ed management of computing and network resources ensures that end-users have a seamless experience,no matter if they are on their mobile phone,at home,or in the car or train.This is because the orchestrator ensures that a broad range of computing environments interact in the backgrou�����nd.One example i
67、s the connected and autonomous vehicles,which will increasingly rely on advanced high-speed and low-latency communication and computing to ensure that they communicate with network and road infrastructure in real time.This will allow these vehicles to contribute to optimising traffic fl�������ow and reduci
68、ng congestion and accidents.22 Th���is technological shift and new paradigm have been confirmed by the large majority of respondents to the Commissions exploratory consultation launched last year to gather views������ and identify Europes needs in terms of connectivity infrastructure to lead the digital tran
69、sformation.In particular,respondents identifi�������ed network virtualisation,network slicing,and Network as a Service,as the technological breakthroughs that will have the largest impact in the coming years.These technologies are expected to drive the shift from traditional electronic communications netwo
70、rks to cloud-based,virtualised,software-defined n�������etworks,reducing costs,improving the resilience and sec�����urity of networks,and introducing new,innovative services,while transforming ecosystem and business models.The results of the exploratory consultation were published in October 2023 and are availa
71、ble at https:/digital-strategy.ec.europa.eu/e����n/news/consultation-electronic-communications-highlights-need-reliable-and-resilient-connectivity.8 Another example is the use of secure high-speed connectivity in order to provide advanced e-health services,including advanced e-health monitoring and e-he
72、alth������ care in remote areas,using low-cost devices.For this,it will be necessary to migrate functionality and use artificial intelligence to the network,which should be located as close to the user as possible.Other technologies that could be part of the health care system of 2030 are sensor-based mon
73、itoring,extended rea������lity(XR)and drones.This technological change triggers the emergence of new business models in the electronic communications services sector.The increasingly complex network operations push companies in different segments of the value chain to work together a������t the infrastructure l
74、ayer while competition at the service layer becomes more complex.Main trends include network sharing,the separation of infrastructure and service l�����ayer and the creation of service platforms based on concepts like Network as a Se�������rvice(NaaS)and IoT.NaaS creates a common and open framework between oper
75、ators that makes it easier for developers to build apps and services in partnership with large cloud providers and content application pr�����oviders(CAPs)that seamlessly communicate with each other and work for all devices and customers.At the same time,it also mak������es it possible for unconventional playe
76、rs in the network services domain,such as cloud hyperscalers,to begin enterprise-grade services in that space23.These changes are being gradually introduced to exploit the full potential of 5G networks,especially for industrial sectors,the so-called vertical�����s such as manufacturing or mobility.With i
77、ts successful industry and public-private partnerships,the EU is currently leading(together with China)the development of these future industrial applications of 5G in vertical industry sec������tors.Examples include operat������ional campus networks,e.g.in factories,ports and mines24 as well as the planned dep
78、loyment of 5G corridors along EU transport networks25.Such changes will be key building blocks of the future 6G computing continuum,which is currently still at the development stage,but which will create further realignment of networks and business cases,and further investment requirement������s for opera
79、tors.Convergence of European electronic communications networks and cloud services to an EU“Telco Edge Cloud”,as envisaged in the Industrial Technology Roadmap of the European Alliance for Industrial Data,Edge and Cloud26 could become a major enabler for hosting and managing network virtuali�������sed func
80、tions,as well as for br����inging complementary services addressing the rapidly growing markets for IoT-related products and services.This is expected to enable the transition to an industrial Internet enabling critical services in a broad range of sectors and activities of great benefit to citizens and
81、 industry alike.Co�������ncrete examples range from robot and drone services for industry,connected and autonomous vehicles interacting with edge networks deployed along the road for smart mobility and smart transportation systems,to use cases with stringent data privacy requirements such as remote patient
82、 healthcare.This calls for the broad availability of computing resources,fully integrated with network resources,to provide the��� data transmission and data processing capacities required by these novel 2�������3 See for instance:Integrated Private Wireless on AWS,https:/ private network solutions on Google
83、Distributed Cloud Edge,https:/ 5G Observatory biannual report October 2023,Omdias Mobile Infr������astructure Intelligence Service.25 https:/digital-s������trategy.ec.europa.eu/en/policies/cross-border-corridors.26 European industrial technology roadmap for the next generation cloud-edge offering,May 2021 https
84、:/ec.euro�����pa.eu/newsroom/repository/document/2021-18/European_CloudEdge_Technology_Investment_Roadmap_for_publication_pMdz85DSw6nqPppq8hE9S9RbB8_76223.pdf 9 applications.The Alliance is currently developing a further thematic roadmap on Telco Edge Cloud,which should be ready by mid-2024.Nowhere is th
85、at more obvious than������� in the city and large urban environments where these sectors and activities come together.The data that they generate can be processed and combined locally,to reduce the use of network resources,orchestrate �����mobility and services in real-time,and optimise health and medical care
86、for the citizen.If the different act��������ors in this ecosystem work together,the Telco Cloud would potentially develop a new generation of compute and data orchestration s�������ystems capable of managing networked resources in environments such as smart cities,as well as providing interoperable services to dev
87、elop and optimise the execution of data-and compute-intensive AI applications.However,this inevitable opening of the traditionally“closed”electronic communications network in a NaaS���� approach exposes network capabilities to third parties and bears the possible risk of large non-EU providers becoming
88、leading players in such ecosystems.In the current geopolitical context and from an economic security poi�����nt of view,this would constitute������ a significant risk of additional dependence on non-EU players in the entire digital service sector.It is therefore key that European players develop the necessary
89、capacities and scale27 to become service platform providers.This creates vast opportunities for the sector,in particular for equipment suppliers.The �����ability of European suppliers to seize them and become leading global providers of 6G equipment will largely depend on how they navigate the broad tech
90、nological changes in the industry and embrace the paradigm shift that come������s with them(see section 2.4.1).The 2023 Beyond 5G/6G Roadmap of EU and US industries is a welcome development in this regard.In the next 5-10 years,both our infrastructure and encryption systems risk being compromised by ever
91、more powerful computing brute force,and by the advent of quantum computing itself.These could render all existing key encryption systems at risk,leavin�����g Europes communication networks and services and sensitive data(health,financial,security or defence-related and more)extremely vulnerable.There is
92、a clear and immediate need for the EU to start preparing its digital assets to face this risk����.A number of recent developments based on quantum technologies,such as quantum key distribution,have significant potential to protect the EUs sensitive data and digital infrastructure.For instance,the EU is
93、working to deploy over the next ten years a fully cert�����ified end-to-end quantum communication infrastructure(EuroQCI)for the distribution of keys used in encryption technologies that will be gradually integrated in the EU Infrastructure for Resilience,Interconnectivity and Security by Satellite(IRIS2
94、).Low Earth Orbit(LEO),and Medium Earth Orbit(MEO)satellite constellations and other non-terrestrial connectivity such as High-Altitude Platforms(HAPs)further extend the boundaries of the technological����� changes to come.To conclude on technological challenges,the sectors of European electronic communi
95、cations networks and services and network equipment stand currently at cross-roads;either they will embrace and endorse technological transformation,or they will leave space to new players,largely f������rom outside the EU,with consequences in terms of EU economic security.27 The concept of scale may be v
96、ery dif�������ferent in a NaaS environment in nature and magnitude compared to the economies of scale of typical current electronic communication networks.10 2.3.Challenges of achieving scale in EU����� connectivity services 2.3.1.Investment needs According to a recent study conducted for the European Commissio
97、n28,reaching cur�����rent Digital Decade targets for Gigabit connectivity and 5G may require a total investment of up to EUR 148 billion,if fixed and mobile networks are deployed independently,and stand-alone 5G-offering European citizens and businesses the full capabilities that can be offered by 5G mob
98、ile networks is deployed.A further EUR 26-79 billion of investments may be required under different������� scenarios����� to ensure full coverage of transport corridors including roads,railways,and waterways,bringing the required total investment needs for connectivity alone to over EUR 200 billion.Despite the
99、need to densify mobile networks to achieve higher performance,EU operators are focussing on reusing existing sites for low and mid-band deployments.However,for future upgrades,e.g.6G or WiFi����� 6 the required network densification is likely to increase by a factor of 2-3 by the end of the decade at lea
100、st in high-density demand areas.Beyond terrestrial connectivity,further investments are required for the integration of advanced satellite services providing complementary solution�������s for backhaul,device connectivity in remote areas not covered by terrestrial technologies or to ensure service continui
101、ty in case of crisis or disaster relief.The succ�����essful ����completion of software and cloud-based solutions to provide NaaS would require additional significant investment capacities.There is an estimated cloud investment gap in the EU of EUR 80 billion until 20272930.A slow transition of EU players tow
102、ards cloud-based solutions for electronic communications services a����nd beyond would present risks of further dependencies in the area of digital services.2.3.2.Financial s������ituation of the EU electronic communications sector The EU capacity to carry out the investments needed to successfully transform
103、the connectivity sector to tackle technological challenges will depend on the financial situation of its electronic communications sector.In this context,the current financial situation of the EU electronic communications������ sector raises concerns for its capacity to find funding for the substantial in
104、vestments that are needed to catch up with the technological shift.The average revenue per user(ARPU)of electronic communications operators in the EU is relatively low ������compared to other economies such as the US,Japan or Sou������th Korea31.This has 28 https:/digital-strategy.ec.europa.eu/en/library/invest
105、ment-and-funding-needs-digital-decade-connectivity-targets.29 European Alliance for Industrial Data,Edge and Cloud:“European industrial technology roadmap for the next-generation cloud-edge”,extrapo�������lating until 2030 the investment gap identified in the Commission Staff Working Document(27.5.2020):Id
106、entifying Eur������opes recovery needs,SWD(2020)98 final/2,Brussels,pp.17-18.30 Synergy Research Group,e.g.based on Q1/2023 data,Investments related to general cloud capacities tailored to the business model of each cloud provider and not significantly overlapping with the general EU connectivity investme
107、nt needs.31 In 2022,mobile ARPU was EUR15.0 in Europe,as opposed to EUR42.5 in th�������e US,EUR26.5 in South Korea,and EUR25.9 in Japan.Fixed broadband ARPU was EUR22.8 in Europe versus EUR58.6 in the US,EUR24.4 in Japan,and EUR13.1 in South Korea.ETNO,State ��������of Digital Communications 2024,January 2024.11
108、led to declining Retur����n on Capital Employed(ROCE)32.The capital expenditure(Capex)per capita in the EU is also lower.In 2022,it stood at EUR 109.1 compared to EUR 270.8 in Japan,EUR 240.3 in the US and EUR 113.5 ��������in South Korea33.During the last decade stocks of European electronic communications net
109、works and services providers have underperformed in both global electronic communications indices and European stock markets34.European providers of electronic communications networks and services also face low enterprise value/EBITDA multiples,suggesting lack of market co�������nfidence in the potential f
110、or sustainable long-term growth in revenues.Against this background,the proportion of at least some of the ele������ctronic communications operators net debt over their EBITDA has continued to grow.In addition,access to finance seems to have degraded as interest rates jumped from historical lows and wides
111、pread risk aversion linked to the new global crises result in macroeconomic uncertainty.As other infrastructure providers,providers of electronic communications networks will also need to recover invest������ment costs over several decades,and even a slight change in the interest rate impacts the financia
11���2、l viability of investment projects.In this context,perception of attractiveness of advanced digital networks by private investors is of crucial importance for the future of connectivity.Certain investors have underlined that mobilising private investments requires a clear business case for profitabi
113、lity and higher margin����s.Profitability depends on the take-up of enhanced fixed and mobile networks,which is itself linked to the development and in���creased take-up of data intensive applications and use cases,e.g.based on edge computing,AI,and IoT.Also,in this context,some stakeholders underlined the
114、 importance of demand-side measures.In this regard,the Union supports the adoption of digital technologies by SMEs throu�����gh the objectives and targets set in the Digital Decade and notably through the European Digital Innovation Hubs,the deployment of data spaces for stakeholders to share and reuse i
115、ndustrial data in a trustwort����hy environment and the access to future“AI f�������actories”35.Increased use of advanced electronic communication services by businesses will reinforce the digitalisation of local ecosystems participating in EU wide supply chains and promote access to infrastructure-intensive a
116、pplications such as generative AI,edge computing and supercomputing,while avoiding possible undue competition distortion.Some investors pointed to the prudential rules for banks and i�����nsurance companies as inhibiting the deployment of capital and the stimulation of equity markets.They argue for reduc
117、ing the levels of required capital set by the legislative framework on prudential regulation.For example,they claim that,in relation to insurance companies,the Solvency II directive36 woul����d enco������urage insurance companies to reduce their exposure to equities for prudential reasons37 as equity prices a
118、re volatile.As a co�����nsequence,more equity investment would arguably lead to low����er solvency 32 As regards fixed markets,according to the 2023 State of the Digital Communications ETNO report,the ARPU of ETNO members was at EUR 21.8 compared to EUR 50.6 in the US and EUR 26.2 in Japan,and only ahead of
119、South Korea(EUR 13)and China(EUR 4.9).33 Ibid.34 State of Digital Communications 2023,ETNO.35 Communication from the Commission to the European Parliament,the Council,the European Economic a�������nd Social Committee and the Committee of the Regions on boosting startups and innovation in trustworthy artifi
120、cial intelligence,COM(2024)28 final.36 Directive 2009/138/EC of the European Parliament and of the Cou����ncil of 25 November 2009 on the taking-up and pursuit of the business of Insurance and Reinsurance(Solvency II),OJ L 335,17.12.2009,p.1155.37 Financer la quatrime rvolution industr������ielle,Philippe Tib
121、i,2019.12 ratios38.The recently agreed current review of the Solvency II framework has addressed these claims,and will result in substantial capital relief thanks to a������� reduction of the risk margin,to changes to the symmetric adjustment and the definition of clear criteria for long-term equity39.Inve
12��2、stments,particularly those in infrastructure,would potentially be stimulated thanks to the increased insurance industrys capacity to invest in EU businesses40.Nonetheless,since equity invested in unlisted stock such as innovative businesses and new electronic communi��������cations operators are still likel
123、y to be deemed riskier,public su�������pport is a necessary incentive.Investors a������lso consider that public support,in particular from the Recovery and Resilience Facility and other EU funds(Next Generation EU,Structural Funds,Connecting Europe Facility(CEF),etc.)will help reach market failure areas,where de
124、mand is insufficient to adequately remunerate private deployment.At the same t������ime,in investors view,public-private partnerships,where the public capital takes th������e form of guarantees or junior co-investment,could possibly be a good and efficient way to help the electronic communications sector fund i
125、ts transformation.Investors finally explained that another element hindering the attractiveness of the European electronic communications market for large investors is its fragmentation and hence the lack of assets with������ sufficient scale.It is common that large investors have minimum thresholds�������� for t
126、heir investments because of their limited capacity to manage and/or mon�����itor their portfolio.This means there are fewer financiers competing for smaller investments than for larger ones,resulting in less favourable conditions.Further,the relative cost of administering large investments is lower than
127、for smaller ones thus investors can offer better conditions.The integrati�������on of national markets could be an opportunity to tap into a larger potential pool of investors and financing conditions for electronic communications investments.In addition,increasing the size of projects can improve their co
128、st efficiency and boost the projects financial viability.A better return profile will improve their attractiveness and eventually the financial conditions.2.3.3.Lack of single market At present,the EU does not have a single market for elec������tronic communications netw�������orks and services,but 27 national m
129、arkets with different supply and demand conditions,network architec�������tures,different levels of coverage of very high-capacity networks,different national spectrum authorisation procedures,conditions and timing,as well as different(albeit partly harmonised)regulatory approaches.The fragmentation does n
130、ot only concern the suppl������y side of the market.Also from the demand side,i.e.end-users,market conditions differ from one Member S������tate to another.This fragmentation was underlined by the majority of respondents to the exploratory consultation on the future of the electronic communications sector and i
131、ts infrastructure41.They highlighted that the removal of obstacles,notably burdensome and/or 38 Deloitte Belgium and CEPS for the European Commission,DG for Financial Stability,Financial Services and Capital Markets Union,Study on the drivers of inve����stments in equity by insurers and pension funds,De
132、cember 2019.39 Confirmation of the final compromise text with a view to agreement,Proposal for a Directive of the European Parliament and of the Council amending Directive 2009/138/EC,2021/0295(COD).40 �������Communication from the Commission to the European Parliament and the�������� Council on the review of the
133、EU prudential framework for insurers and reinsurers in the context of the EUs post pandemic recovery,COM(2021)580,2021.41 The results of the exploratory �������consultation were published in October 202������3 and are available at:https:/digital-strategy.ec.europa.eu/en/news/consultation-electronic-communication
134、s-highlights-need-reliable-and-resilient-connectivity.In this regard,the large majority of the respondents to this question(including telecom 13 fragmente�����d������ sectoral regulation,can create incentives for cross-border consolidation and emergence of a fully integrated Digital Single Market.Concerning th
135、e barriers to market integration,the majority of the respondents to the exploratory consultation42 called,in particular,for a more integrated spectrum ma�����rket and a more harmonised approach to spectrum management across the EU.They suggested that it would be appropriate to align the approaches relate
136、d to,for example,duration of licences,reserve prices,annual cost of spectrum,or spectrum sharing practices.Radio spectrum policy is an area of shared competence between the EU and Member States.The EU adopts rules,in particular for the EU-wide designation of frequency bands under harmonised techni�������������ca
137、l conditions.Member States action focuses on the implementation of spectrum authorisation,management �������and use.H�����owever,the way spectrum is managed and used in one Member State has an impact on the internal market as a whole,for example through disparate starting times in the development of new wireles
138、s technologies or new services or through harmful cross-border interference,with further possible repercussions for EU competitiveness,resilience and technological leadership.Therefore,it is imperative that spectrum is managed in a more coordinated way among all Me����mber States to maximise its social
139、and ec�����onomic value and enhance terrestrial and satellite connectivity across the entire EU.The past attempts for more EU coordination,convergence and certainty in spectrum manag������ement,for example,in the context of the proposal for a Telecommunications Single Market regulation43 and the European Elect
140、ronic Communications Code(hereinafter referred to as the“Code”)44,were not successful in many respects.Ultimately������,this had detrimental consequences for the EU as a whole.For example,the authorisation process for bands anticipated to enable future 5G deployment started in 2015 in the first Member Sta
141、tes45 and is not yet fully completed n�������ow in 2024,despite the deadlines set at EU level.The authorisation process for the use of the 800 MHz and 2.6 GHz bands for 4G took 6 years for 26 Member States and even 10 years for 27,despite the absence of an exceptional pandemic event as for 5G46.This has re
142、sulted in fragmented 4G ����and 5G roll-out landscapes across the EU,where some Member States were almost one wireless technology generation behind others.and satellite business associations,vendors,operators as well as NGOs)noted that the digital single market is hampered by the fragmentation of the se
143、ctor into national markets.This is due both to cultural and diverging market circums���tances and the lack of full harmonisation of sector rules(e.g.building lawful interception capabilities,data retention,data protection,reshoring requirements,cybersecurity and reporting obligations and network/servic
144、e incident reporting requirements,spectrum auction conditions,etc.),which is also caused by a slow and piecemeal implementation of EU rules at nationa�����l level and fragmented approaches to enforcement.42 When replying to the consultation,th�������e majority of the respondents,mostly companies(ECN providers a
145、nd digital platforms),business associations and consumer organizations,welcomed the idea �����of a more integrated spectrum market and a harmonised approach to spectrum management across the EU.43 COM(2013)627 final.44 Directive(EU)2018/1972 of the European Parliament and of the Council of 11 December 20
146、18 establishing the European Electronic Communications Code,OJ L 321,17.12.2018,p.36.45 Commission study on assessing the efficiency of radio spectrum award processes in the Member ������States,including the effects of applying t�����he European Electronic Communications Code,available at https:/digital-strate
147、gy.ec.europa.eu/e�����n/library/study-assessing-efficiency-radio-spectrum-award-processes-member-states-including-effects-applying.46 Commission study on spectrum assignment in the European Union,available at https:/op.europa.eu/en/publication-detail/-/publication/2388b227-a978-11e7-837e-01aa75ed71a1/lan
148、guage-en.14 Moreover,in certain cases where spectrum bidders ended up paying higher prices due to artificial scarcity created by auction design,this has been associated with a reduction in investment capacities and delays in services deployment by providers of electronic communications���� networks and
149、services.Ultimately,it is the consumers and business users who have paid the price in terms of suboptimal quality of services,which ultimately negatively impacts EUs economic growth,competitiveness and cohesion.There are als�������o national rules beyond sector spe������cific electronic communications legislatio
150、n imposing obligations,as regards,for instance,lawful interception,data retention or localisation of Security Operations Centres,that were also raised in the exploratory consultation as barriers to the full integration of the Single Market4�������7.In these areas,lack of un��������iform legislation at EU level con
151、tributed to significant fragmentation(e.g.different duration of data retention obligations,localisation requirements for Security Operations Centres,lack of mutual recognition for security vetting for relevant staff)preventing a provider operating a network in more �����than one Member State from exploit
152、ing economies of scale.Regulatory fragmentation is mirrored in the market structure.While there are �������around 50 mobile operators,and more than 100 fixed operators in the EU,only few European operators(e.g.Deutsche Telekom,Vodafone,Orange,Iliad and Telefonica)are present in several national markets.Whe
153、n it comes to mobile markets,at service level,16 Member States have three mobile network operators,nine Member States have four and two Member States have five.In certain Member States,in terms of ������distinct mobile electronic communications network infrastructures,the number is lower than the number o
154、f service providers due to existing network sharing arrangements(e.g.in Denmark or Italy).Even the mobile operators that are part of corporate groups with a large footprint across the EU,operate within national markets and do not se�����em to harmonise their offerings and operational systems at EU level,
155、due to the inherently different market and regulatory landscapes,beyond the nee�����d to ensure affordability in Member States with lower purchasing power.Against this backdrop of fragmentation in the EU(which is specific to the EU compared to other regions of the world)and low profitability levels,the q
156、uestion arises as to whether industrial policy measures furt�����her facilitating the cross-border provision of ele�����ctronic communications networks or different forms of cooperation upstream could allow operators to acquire sufficient scale,without compromising downstream competition.Some operators are of
157、 the view that there are no obstacles to cross-border p�������r���ovision of networks and services other than the net negative efficiencies and synergies(despite expected cost reductions which could be allowed by more centralised operations,especially in virtualised networks)that are due to fragmented regulat
158、ory conditions.Cross-border consolidation in itself has never been ��������a problem from a competition standpoint because of the national dimension of the EU electronic communications markets.However,as long as the benefit����s of cross-border consolidation are limited by the persistence of national regulatory
159、 framework�����s and the lack of a genuine single market,it cannot as such overcome the fallbacks mentioned earlier.47 The results of the exploratory consultation were published in October 2023 and are availab������le at https:/digital-strategy.ec.europa.eu/en/news/consultation-electronic-communications-highli
160、ghts-need-r������eliable-and-resilient-connectivity.For this point see page 12 under point ii.Obstacles to the Digital Single Market.15 While prices and coverage differ considerably between Membe�����r States48 due to the inherently different market and regulatory landscapes,beyond the need to ensure affordabi
161、lity in Member States with lower purchasing power,mobile and fixed broadband prices are typically lower in the EU compared to the US for the vast majority of tariffs,bringing signif�������icant s�����hort-term consumer benefits.At the same time,coverage for fibre is higher in the EU and basic 5G coverage is com
162、parable to the US levels.However,while the single market,on average,delivered on price,it did not deliver on the mass deployment of advanced infrastructures and services like 5G����� standalone or the proliferation of advanced industrial and IoT services49.Overall,the fragmentation of the EU market for e
163、lectronic communications networks and services along national borders impacts the ability of operat�����ors to reach the scale n�����eeded to invest in the networks of the future,in particular in view of cross-border services,important for an effective deployment of IoT,and a more centralized operation.2.3.4.
164、Convergence and level playing field The convergence of electronic communications networks and services and cloud infrastructures doe������s not only concern the infrastructure layer,but also the service operations.As explained in section 2.2 ������above,connectivity markets are facing transformative technologic
165、al developments the result of which will be both a converged suppl������y(work and service provision)as well as a converged demand by end-users.Yesterdays separation between“trad�����itional”electronic communications networks/service providers and cloud or other digital service providers will tomorrow be super
166、seded by a complex converged ecosystem.These develop��������ments raise the question whether the players in such converged ecosystem should not fall under equiv�������alent rules applicable to all and whether the demand side(i.e.end-users and in particular consumers)should not benefit from equivalent rights.Curren
167、tly,the existing EU regulatory framework for electronic communications networks and services does������� not establish obligations related to the activities of cloud providers and does not regulate the relationship between the various players in the new complex digital infrastructure ecosystem.More specifi
168、cally,the cloud infrastructure and services provision are not in the scope of the Code(contrary to the recent NIS2 Directive50 for instance).Even if cloud providers run large(backbone)electronic com������munications networks,these networks are exempt from parts of the electronic communications regulatory
169、framework,notably in the area of access regulation and dispute resolution.More than 6��������0%51 of the international traffic transits through submarine cables,which do not belong to“public electronic communication network operators������”within the meaning of the Code.Moreover,large cloud providers operate thei
170、r������ own backbone networks and data centres and hand over the traffic deep into the ne�����tworks of public electronic communication network 48 Mobile and fixed broadband prices vary widely across the EU not only in nominal terms but also at power purchasing parity.See European Commission,Directorate-Genera
171、l for Communications Networks,Content and Technology,Mobile a�������nd fi�����xed broadband prices in Europe 2021 Final report and executive summary,Publications Office of the European Union,2022,available at https:/data.europa.eu/doi/10.2759/762630.49 2023 Report on the state of the Digital Decade,available at
172、 https:/digital-strategy.ec.europa.eu/en/l���ibrary/2023-report-state-digital-decade.50 Directive(EU)2022/2555 of the European Parliament and of the Council of 14 December 2022 on measures for a high common level of cybersecurity across the Union,amending Regulation(EU)No 910/2014 and Directive(EU)2018
173、/1972,and repealing Directive(EU)2016/1148(NIS 2 Directive),OJ L 333,27.12.2022,p.80.����51 BoR(23)214,Draft BEREC R������eport on the general authorization and related frameworks for international submarine connectivity.16 operators.Consequently,traffic transits mostly on private networks,which are largely u
174、nregulated,rather than on public ones.Another distinction made in the Code is between the kind of service provided;for example,most obligations apply to providers of internet ac�����cess services and of number-based interpersonal communications services(NBICS)while providers of number-independent interpe
175、rsonal communications service(NIICS)are subject to only a few obligations and are exempt for instance from contribution to the funding of the Universal Service or the financing of sector regulation.Whilst both NIICS and cloud computing services are wit����hin the scope of the Digital Markets Act52,those
176、 rules on�������ly apply to gate�������keepers designated for these specific core platform services.2.3.5.Sustainability challenges The ICT sector accounts for between 7 and 9%of global electricity consumption(forecast to rise to 13%by 2030)53,around 3%of global greenhouse gas emissions54,and increasing amounts o
17������7、f e-waste.Yet,if properly used and governed,digital technology can help cut global emissions by 15%55,outweighing the emissions caused by the sector.For instance,smart building design has the potential to generate energy sav����ings of up to 27%56 and smart mobility applications have been shown to be ab
178、le to reduce transport emissions by up to 37%57.Connected and Automated Mobility is expected to be o�����ne of the main drivers to decarbonise the transport sector and 5G is expected to be one of its main enablers.However,significant further efforts are needed to apply digital technology systematically a
179、nd make sure it powers solutions carefully designed according to circular,regenerative principles.The“softwarisation������”and“cloudification”of the next generations of electronic communications networks hold the promise of efficiency gains for all sectors,but also present new challenges in terms of energ
180、y consumption(e.g.Open Radio Access Network������-RAN-in cellular networks).Increased energy consumption due to step changes in traffic load has a cost in itself that has significantly increased in recent years with rising energy prices.At the same time,high energy costs could incentivise investments into
181、 more energy-efficient and low-carbon network operations and technologies with less e-waste.Modern digital networks ca�����������n contribute significantly to sustainability.Concrete examples include the deployment and adoption of new and more efficient technologies such as fibre,5G and 6G,and the phasing out
182、of legacy fixed and mobile networks.Also,the use of more efficient codecs(coders-decoders)58 for data transmission is essential.Newer generation video codecs are inherently more sustainable by minimising outgoing energy and power at the same video quality.At the same time,proper attent���������ion and invest
183、ments,including sustainable financing,need to be ensured so that connectivity can accelerate and deliver on the digital enablement to green other sectors,through smart digital solutions that reduce the climate and environmental 52 Regulation(EU)2022/1925 of the E������uropean Parliament and of the Council
184、 of 14 September 2022 on contestable and fair markets in the digital sector and amending D��������irectives(EU)2019/1937 and(EU)2020/1828(Digital Markets Act),OJ L 265,12.10.2022,p.1.53 Strateg���ic Foresight Report 2022;EU Action Plan on Digitalising the Energy System.54 The Shift Project,“Dployer la sobrit n
185、umrique”,October 2020,p.16;��������World Bank 2022.55 World Economic Forum 2019.56 https:/www.buildup.eu�����/en/news/overview-smart-hvac-systems-buildings-and-energy-savings-0.57 TransformingTransport.eu,EU-funded Horizon 2020 Big Data Value Lighthouse project.58 A codec is a process that compresses large amoun
186、ts of data most commonly a video stream-before their transmission and decompresses ��������the�������m after the reception.17 footprint across industrial processes,energy systems,buildings,mobility,and agriculture and support the efforts towards climate neutral and smart cities.2.4.Need for security in the supply
187、and in the operation of networks 2.4.1.Challenge of tru�����sted suppliers In a geopolitical environment increasingly marked by tension and conflict,the growing requirement for security and resilience of key enabling communications tech������nologies and critical infrastructure highlights the need to rely on d
188、iversifie������d and trusted suppliers,to prevent vulnerabilities and dependencies,with potential knock-on effec�����ts on the entire industrial ecosystem.The EU 5G Cybersecurity Toolbox59 for example put forward a set of recommended measures to mitigate the risks to 5G networks,notably the assessment of the r
189、isk profile of suppliers and the applic�������ation of restrictions for suppliers considered as high risk,including necessary exclusions from key assets.In this respect,in its Communication������� of 15 June 2023 on the“Implementation of the 5G Cybersecurity Toolbox”60 the Commission considered that Huawei and ZT
190、E present in fact materially higher risks than other 5G suppliers and confirmed tha���t decisions adopted by Member States to restrict those suppliers are justified and compliant with the 5G Toolbox.Gaps left by these high-risk vendors in the supply chain require the development of new capacities provi
191、ded by existing or new actors.In this context,Research&Innovation(R&I)efforts in ke�����y technologies relevant for secure communications networks will have to be stepped up to ensure that a sufficient level of intellectual property and production capacity remains available across the entire EU supply ch
192、ain,at all times.The objective is not only to ensure that the EU rema�����ins among the global leaders in communications systems,but also to achieve leadership in the development of new capabilities in related areas such as edge cloud,radio frequency identity chips tec������hnology,quantum communications,quant
193、um resilient����� cryptography,non-terrestrial connectivity,and submarine cable infrastructures.2.4.2.Security standards for en������d-to-end connectivity To achieve the highest security and resilience,the EU should also lead the development of security standards covering the entire value stack,from end-to-end
194、 and from the hardware layer up to the service layer(e.g.secure messaging and v�����ideoconferencing standards).The challenge for the EU is to ensure that such developments result in common and interoperable security standards for all key infrastructural elements underpinning ������sensitive communications inf
195、rastructures.The Commission is working with Member States to establish the EU Critical Communication System(EUCCS)to connect communication networks of all public law-enforcement,civil protection and safety responders in ����Europe by 2030 to allow for seamless critical communication and operational mobi
196、lity across the Schengen area61.The related setting of mission critical standards will enhance strategic autonomy in a particularly sensitive segment of the com������munication sector.59 https:/digital-strategy.ec.eur�����opa.eu/en/news/connectivity-toolbox-member-states-agree-best-practices-boost-timely-deplo
197、yment-5g-and-fibre.60 C(2023)4049.61 EUCCS is based on projects funded by the EU security r�������esearch programme and the Internal Security Fund.The current rollout of testbeds in Member States will also establish the link to EU connectivity assets in Space,in line with the EU Space S�����trategy for Security
198、 and Defence.18 The new digital era will be based,among others,on quantum technologies for secure connectivity and quantum computing.Commun������ication networks and the way data are protected will experience a paradigm shift as a direct consequence of advances in quantum computing.As safeguarding our dat
199、a and securing communication are vital for our society,economy,infrastructure,services,and prosperity,as well as our political stability,we need to anticipate threats coming from potential malicious use of future quantum computers,which could put our traditional methods of e�������ncryption at risk.The Cyb
200、er Resilience Act(CRA),which is set to enter into force later this year,will contribute significantly to securing EUs digital infrastructure.It places security-by-design obligations on the manufacturers of hardware and software products,covering the entire life cycle of such prod�����ucts from their desi
201、gn and development to their ma����intenance.The CRA not only covers many of the products deployed in digital infrastructures,such as routers,switches or network management systems,but also requires the manufacturers of connectable hardware and������ software products at large to protect the confidentiality an
202、d integrity of data by state-of-the-art means.This could entail,where appropriate,the use of quantum-resistant cryptography.To support manufacturers in their implementation,the Commission will request the de�����velopment of European standards by the European Standardisation Organisations.In addition,the
203、 recently adopted European Cybersecurity Scheme on Common Criteria(EUCC)will allow manufacturers of technological components,such as chips,to provide security assurance in a harmonised manner under the EUs Cybersecurity Act.2.4����.3.Secure and resilient submarine cable infrastructures A precondition fo
204、r se������cure communications is a higher level of resilience and integration of all communication channels:terrestrial,non-terrestrial and,importantly,submarine.In the current context of increased cybersecurity and sabotage threats,governments in all regions are pay����ing particular attention to their relia
205、nce on critical submarine cables.Indeed,over 99%of intercontinental data traffic is carried through submar�����ine cables,and three insular EU Member States,Cyprus,Ireland and Malta,as well as a number of islands in other Member States and outermost regions are highly dependent on them.In particular,Russ
206、ias war of aggression against Ukraine has had a significant impact on aware�����ness about the security of communications networks,including submarine cables,given it������s potential capability to disrupt cables and suspicious monitoring activities of Russian vessels.Europe has global leaders in fibre product
207、ion.However,since 2012,large �����non-EU providers have been increasingly investing in own infrastructures,which is already leading to strategic dependencies,which may be further exacerbated going forward.In the EU,there have been repeated calls to strengthen the security and resilience of submarine cabl
208、e in�����fras�������tructures,including increasing public funding to support private investment in a challenging environment.For instance,the Nevers Call of March 202262 recognised the utmost importance of critical infrastructure,such as electronic communications networks and digital services,to many critical f
209、unctions����,and the fact that the latter are a prime target for cyberattacks.The Council,in its Conclusions on the EUs Cyber Posture of 23 May 2022 and on the EU Policy on Cyber Defence of 22 May 2023,requested risk evaluations and scenarios to be undertaken.In �������its Critical Infrastructure Resilience Re
210、commendation on a Union-wide 62 https:/presse.economie.gouv.fr/08-03-2022-declaration-conjointe-des-ministres-de-lunion-europeenne-charges-du-numerique-et-des-communications-electroniques-adressee-au-secteur-numerique/.19 coordinated approach to streng������then the resilience of critical infrastructure o
211、f 8 December 2022,the Council set out targeted actions at EU and Member States level for enhanced preparedness,enhanced response and international cooperation.These actions focus on critical infrastructure,in�������cluding those with significant cross-bor������der relevance and in the identified key sectors ener
212、gy,transport,space,and digital infrastructure.In the State of the Digital Decade report 2023,the Commission underlined the importance of making progress towards �����more resilient and more sovereign networks and in particular to limit the vulnerabi������lity of the EUs key infrastructure,including submarine n
213、etworks.It also issued a clear recommendation to Member States to boost the investments necessary for the security and resilience of such infrastructures.Membe�������r States have also committed to reinforce Internet connectivity between Europe and its partners,in the Ministerial Declaration on“European Da
214、ta Gatewa������ys as a key element of the EUs Digital Decade”.Moreover,the EU-NATO Task Force on the resilience of critical infrastructure discussed submarine infrastructure on several occas������ions.Its Final Assessment Report includes a recommendation for EU and NATO staffs to“explore possibilities for excha
215、nges on how t�������o improve the monitoring and protection of critical infrastructure in the maritime domain by relevant authorities and discuss ways to enhance maritime situational awareness”.Staff exchange have intensified in the context of the Structured Dialogue on Resilience,including in lig������ht of the
216、 establishment of the NATO Critical Under������sea Infrastructure Coordination Cell to address the security of inter alia submarine cables.Incidents such as in the Baltic Sea63,following which Finland activated the EU Hybrid Toolbox mechanism64,have however demonstrated that elements of submarine cable in
217、frastructure remain vulnerable,even if the system itself is resilient due to multiple redundancies.This underlines the need to further advance and coordinate work at EU level to foster cable infrastructure securi�������ty and resilience.Consequently,the Eur����opean Council on 27 October 2023 consequently stre
218、ssed“the need for effective measures to streng�����then the resilience and ensure the security of critical infrastructure”,while underlining“the importance of a comprehensive and coordinated approach.”As mandated by the 2022 Council Recommendation as regards submarine cable infrastructures,the Commission
219、 carried out studies and consulted relevant stakeholders and experts on appropriate measures in relation to possible significant incidents regarding submarine infrastructure.The results of the study will be shared with Member Sta�������tes at the appropriate confidentiality level.A key conclusion is that t
220������、he current framework in the EU cannot fully address the challenges identified.Concrete elements curren����tly lacking include an accurate mapping of existing cable infrastructures informing a consolidated EU-wide assessment of risks,vulnerabilities and dependencies,a common governance of cable technolog
221、ies and cable-laying services,ensuring rapid and secure repair and maintenance of cables,as well as the identifi������cation and funding of critical intra-EU and global cable projects.63 A submarine gas pipeline(between Finland and Estonia)and electronic communications����� cables(between FI and EE,and between
222、 SE and EE)were damaged.64 Council conclusions of 21 June 2022 on a Framework for a coordinated EU response to hybrid campaigns.20 3.MASTERING THE TRANSITION TO THE DIGITA�������L NETWORKS OF THE FUTURE-POLICY ISSUES AND POSSIBLE SOLUTIONS 3.1.Pillar I:Creating the“3C Network”-“Connected Collaborative Comp
223、uting”As described in earlier sections,people and devices communicating with each other,doctors caring for their patients at a distance,buildings becoming intelligent through sensors,����and other future applications facilitating busin����ess and improving the lives of citizens depend on the availability of
224、 high-performing di������gital infrastructures.The advancement of on-device edge technology is expected to facilitate the presence������ of significant computational capacity,especially those equipped with AI processors,in a wide range of devices,including robots,drones,medical devices,wearables and self-drivin
225、g cars.Computation is no longer bound to dedicated computin�������g environments such as data centres.��������Instead,it has become embedded and ubiquitous in almost everything.This will allow to combine on-device edge with the rest of the broad range of edge computing categories and different types of cloud servi
226、ces in collaborative computing environments65.However,the integration of these different computing resources with various network capacities will require intelligent orchestration,that also allows optimisation for security and sustainability cons�����iderations.As section 2.2 describes,just as connectivi
227、ty and computing are converging,the companies in these differe�����nt segments of the value chain also need to work together,including chips manufacturers,electronic communications network equipment providers,edge and cloud service providers.But the different sectors are fragmented������ and,as well as lacking
228、 scale,they do not have a common appr��������oach to the innovation necessary to deliver next generation connectivity and computing.Thus,as well as orchestration in the technical sense,these sectors require close collaboration in order to succeed.We need to ensure that these innovations are implemented in t
229、he������ EU and safeguard our economic security and prosperity.In particular,it is of key importance that EU industry has sufficient technology capacity in key parts of the digital supply chain and is able to reap economic benefits in the most attractive parts of the digital value chain.The goal is to fos
230、ter a vibrant co�������mmunity of European innovators,creating the“Connected Collaborative Comput�����ing”Network(“3C Network”),an ecosystem that spans semiconductors,computational capacity in all kinds of edge and cloud environments,radio technologies,to connectivity infrastructure,data management,and applicat
231、ions.3.1.1.Capacity building th���rough open innovation and technology capabilities As hybrid networks,edge computing,and full cloud migration change the architecture of connectivity infrastructure,the historical strength of Europe in the network equipment and service industry is at risk.It is therefor
232、e important to ����safeguard EU global leadership in electronic communications network equipment and facilitate the build-up of further indus�������trial capacities in this transition towards interoperable cloud-based networks and the integration of telco-edge infrastructures and services.Next to industrial ca
233、pacity,it is equally important for the EU to strengthen its technological innovation capabilities as well as developing the necessary knowledge and skills.65 Collaborative computing environments have also been referred to in literature as Swarm computing,Ambient Compu�����ting,and Tactile internet,among
234、other additional terms.21 EU businesses increasingly partner with non-EU players,both within the electronic communications services ecosystem but also in the supply industry.Whil�����e such partnerships with actors from like-minded countries can generate synergies and benefits,a potential dependency on a
235、 small number of suppliers of critical infras�����tructures and services,such as cloud,edge or AI tools,or submarine cable infrastructures,bears the risk of new bottlenecks or lock-ins66.The goal must be to create an equally strong dynamic for partnership between businesses within Europe.In the area of s
236、emicondu������ctors,the EU has������ reacted to reverse this trend:with the Chips Act67,the EU has put forward an ambitious programme which has already mobilised more than EUR 100 billion of public and private investments.But when it comes to connectivity infrastructures,an industrial policy of similar magnitud
237、e to incentivise investments by EU players and catalyse the 3C Network to enable future applications is cu�����rrently missing.Nevertheless,in the equipment sector,the EU has a solid base that it can build upon.Today,it is the home of two of the three largest suppliers of digital network equipment,both a
238、s regards global sales market share and share of standard essential patents.Following decades of success in shaping mobile communication standards and driving innovation in the �����EU and globally,the challenge is to build on this leading position and leverage it to the broader supply and value chain,su
239、ch as in the area of edge and cloud computing but also chips,where Europe starts from a weaker position.This extends to complementary infrastructures,such as submarine cables or even non-terrestrial connectivity.As for production,deployment,and operationa����l capacities,Europe can also build on its str
240、ength when it comes to R&I ������in the upstream part of the digital value chain.The EU already hosts a solid R&I base for networks,with globally renowned������� scientific excellence on which future R&I ecosystems can build.The geopolitical context and the trend towards ever more critical applications,such as b
241、lockchain in finance,connected trucks in logistics,or telemedicine,call for infrastructure security and resilience by design.These d�������esign criteria therefore need to be placed at the forefront of our R&I efforts.However,the transformation of the EUs connectivity industry requires significant investme
242、nt capacities,in particular when compared to the massive investments made by large cloud providers into cloud,edge,and AI capacities.There������ are a number of EU funding instruments and programmes th������at already support private investments in R&I in relation to the communications sector.These include the
243、Smart Networks and Services Joint Undertaking(SNS JU)under Horizon Europe,but also InvestEU,the Digital Europe Programme(DEP),and th�����e Connecting Europe Facility(CEF)Digital.The SNS JU is the current EU platform for R&I funding towards 6G systems in cooperation between industry and public actors.One
244、of its main objectives is to �������leverage the EUs strength in network supply towards the broader value chain including cloud and software as well as de�������vices and components.The SNS JU already addresses several industry-led R&I needs(mostly in anticipation of 6G):research on concepts,architectures and cor
245、e components of 6G systems,large-scale trials and pilots,standardisation,virtualisation of networks,cloud software,as well as AI-enabled radio access networks.This current scope is,however,too narrow to 66 Commission study on 5G Supply Market Trends,August 2021,available���� at https:/digital-strategy.e
246、c.europa.eu/en/library/commission-publishes-study-future-5g-supply-ecosystem-europe.67 Regulation(EU)2023/1781 of the European Parliament and of the Counci�������l of 13 September 2023 establishing a framework of measures for strengthening Europes semiconductor ecosystem and amending R�����egulation(EU)2021/694
247、(Chips Act)(Text w�����ith EEA relevance),OJ L 229,18.9.2023,p.153.22 address the challenges identified.Moreover,the existing budget of EUR 900 million for 2021-2027 is focused on R&I activities.This represents a small amount in the face of those challenges,compared to what would be required to catalyse
248、the next generation connectivity ecosystem covering the entire computing continuum.In December 2023,the Commission approved up to EUR 1.2 billion of State aid by seven Member States for an Important Project of Common Europea������n����� Interest(IPCEI)in Next Generation Cloud Infrastructure and Services(IPCEI
249、CIS)����,which is expected to unlock additional EUR 1.4 billion in private investments68.Already in June 2023,the Commission approved another IPCEI to support research,innovation and the first industri�����al deployment of microelectronics and communication technologies across the value chain(IPCEI ME/CT),in
250、volving 14 Member States,c�������ounting with EUR 8�����.1 billion in public funding,unlocking EUR 13.7 billion in private investments.Leading chip suppliers and network equipment vendors participate,to develop advanced chips for electronic communications networks.3.1.2.Way forward To ensure a more efficient us
251、e of resources,the EU needs to establish a coordinated approach to the development of integrated connectivity and comput���in�������g infrastructures,making sure that todays connectivity providers become tomorrows providers of collaborative connectivity and computing,capable of orchestrating the different com
252、puting elements that this ecosystem requires.To do so it is ����not only necessary to develop a synergetic ecosystem between actors in the different sectors,but also to rethink the interplay and synergies that can be established between existing EU ��������funding programmes.This is necessary in order to maximi
253、������se the impact of R&I in communications and computing networks,but also capacity building and ������pre-deployment,especially given the convergence of technologies and services(cloud-edge continuum,AI,connectivity).These programmes could be built around the overall objectives of improving the EUs industria
254、l capacities,of contributing to a secure and resilient connect�����ivity and computing infrastructure,and of bolstering Europes competitiveness.Ultimately,this could provide the environment for future networks and applications being developed,tested,deployed,and integrated in the EU.A key step towards th
255、e 3C Network could be taken by proposing for consideration in fort������������hcoming work programmes a number of large-scale pilots that set up end-to-end integrated infrastructures and platforms and bring together players from different segments of the connectivity value chain and beyond.These could be consid
256、ered for funding under the Horizon Europe programme or its successors.If pursued,these pilot infrastructures would be used to test innovative technologies and applications(including demos������,proof of concepts and early deployment of technologies).They could be attached,where appropriate,to the European
257、 network of competence centres in semiconductors,which are maximising synergies with the European Digital Innovation Hubs.Initial pilots could focus on 5G corridors,e-health and smart communities.T�����hese initial,up to three large-scale �����pilots would not only promote exchanges between players from the t
258、raditional electronic communications value chain and players along the broader computing continuum,but also with non-digital sectors,ensuring emphasis ������on concrete applications.The integrated infrastructures and platforms would bring together not just the key technologies from startups to large busin
259、esses but also researchers and attract talent to develop knowledge and skills.68 https:/ec.europa.eu/commission/presscorner/detail/en/ip_23_6246.23 Europe can build �������again on existing initiatives to scale up innovative technologies and applications.One example is the development of 5G corridors,funde
�������260、d under the CEF Digital programme,where the corridors can be used for testing and piloting new technologies and applications,in particular connected and autonomous driving but also advanced logistics and IoT applications.Another example is the smart communities,where pilot architectures could be use
261、d to trial AI systems and applications funded under the EUs AI flagship,in order to maximise synergies and ensure that computing at the edge serves as a fuelling station for AI-powered algorithms.As well as urban agglomerat�������io������ns,a smart communities pilot could account for specific challenges of rural
262、 surroundings,so that any solutions are rural ready.To succeed,Europe must mobilise all the relevant actors into a collaborative computing ecosystem.As well as the 6G Industry Association,the key privat������e sector partners in the SNS JU,the European Alliance for Industrial Data,Edge and Cloud(the Cloud
263、 Alliance)brings together actors in the cloud and edge environment.Concretely in the next few years,the SNS JU could coordinate the creation of immediate synergies with relevant programmes and IPCEIs.Following the publication of this White Paper,the Commission will shortly start develo���ping with stak
264、eholders the specifications of this task,building notably on the ongoing work to further develop and deploy European Telco Edge Cloud capacities�����,as envisaged by the Industrial Technology Roadmap developed by the Cloud Alliance.The existing IPCEIs,in particular in the area of microelectronics and con
265、nectivit�����y as well as next generation cloud infrastructure and services,could be used to structure innovation and accelerate market take-up.In October 2023,the Commission launched a Joint European Forum for Important Projects of Common European Interest(JEF-IPCEI)to focus on identifying and prioritis
266、ing strategic technologies for the EU economy that could be relevant candidates for future IPCEIs.As part of the JEF-IPCEI,and drawing from the experience under the Chips Joint Undertaking(Chips JU),CEF2,DE������P,and relevant national and regional funds,the possibility of supplementing these measures wit
267、h a new IPCEI to tackle the need for large scale infrastructure deployment together with the exploration of integr�������ation of add������itional target areas along the computing continuum such as chips in order to respond adequately to the massive future compute demands of artificial intelligence could be disc
268、ussed.In addition,the Strategic Technologies for Europe Platform(STEP)will boost investments in critical technologies in Europe including deep and di������gital technologies.STEP also ������introduces the Sovereignty seal the EU quality label for sovereignty projects.In the longer term,to further leverage EU te
269、chnology capacities,it would need to be determined whether and how related areas that are crucial for future networks could be brought under a single cooperati�������ve governance.The appropriate mix of budget sources at Union,national and industry levels would also need to be determined,including the role
270、 of different possible EU programmes.Inspiration could be taken from the examples of the recent AI innovation package69 and the Chips Act,which extended th������e mandates of res�������pective current Joint Undertakings on European High Performance Computing and Chips(EuroHPC JU and Chips JU).Future research pri
271、orities could include security solutions in critical hardware and software modules,interoperability and federation between edge and cloud infrastructures supported by open-source activities,diversified supply chains for products,components,and materials,while strengthening know-how in the EU,and su��������s
272、tainability solutions cov������ering various aspects of the 69 COM/2024/28 final.24 networking domain(“Sustainable 6G”)and a variety of the vertical industries,such as manufacturing,transport,energy,and agriculture(i.e.“6G for sustainability”).Increased and better aligned R&I activities that are embedded
273、into an industrial strategy could strengthen Europes technology capacity,create synergies,ensure coher�����ence,and leverage the multiplier effect of EU actions for private investments.It could also prov�������ide the means of ensuring the EUs security and resilience in this domain as well as improve cooperatio
274、n among European players in an ecosystem that spans �����the whole computing continuum,supporting them to compete on an equal footing with global competitors.The goal would be to ensure the availability of European solutions able to establish a����� single entry point for EU funding across the whole continuum
275、 from radio freque�������ncy to chips to software to algorithms to edge and cloud compute capacity,so that Networks-as-a-Service are not an end in themselves but an enabler of orchestration,fuelling actual services and applications made in Europe.3.1.3.Summary of possible scenarios Scenario 1:The Commissio
276、n may consider proposing large-scale pilots that set up end-to-end integrated infrastructures and platforms for telco cloud and edge.In a second step these pilot ����infrastructures would be used t���o orchestrate the development of innovative technologies and AI applications for various use cases.Scenario
277、 2:The possibility of following-up the accomplis�����hments of IPCEI CIS by a ne�����w infrastructure-focussed IPCEI could be discussed by the Commissions Joint European Forum for Important Projects of Common European Interest(JEF-IPCEI),which is tasked with identifying and prioritising strategic technologies
278、 for the EU economy that coul������d be relevant candidates for future IPCEIs.Scenario 3:Massive investments in connectivity capacity are required to support the creation of a collaborative connectivity and computing ecosystem.The Commis�����sion may consider different options in order to frame these investmen
279、ts into a simplified and coordinated support framework for a truly digital single market drawing on European and national,public and private investments.o This should streamline procedures and improve synergies between existing instruments and programmes(including based on the experience wi���������th the Ch
280、ips Joint Undertaking,Important Projects of Common European Interest,the Connecting Europe Facility and t���he Digital Europe Programme),possibly tasking as a pilot under the current Multiannual Financial Framework the Smart Networks and Services J����oint Undertaking(SNS JU)to adopt a more coordinating ro
281、le,and by liais������ing with stakeholders such as the European Alliance for Industrial Data,Edge and Cloud as appropriate).o This should explore means to ensure strengthening coherence,simplification and clarity of future support action,without prejudic�����e to institutional programme design and budget alloc
282、ation prerogatives under the next Multiannual Financial Framework.25 3.2.Pillar II:Completing the Digital Single Market 3.2.1.Objectives������ One of the main objectives of the Code is to promote connectivity by putting in place a regulatory framework conducive to more investment in very high-capacity net
283、works.With this objective in mind,a number of legal provisions �������in the area of access regulation and spectrum management were designed to facilitate investment,and to cut red tape.However,despite a number of new provisions introduced in the Code,the results have not been satisfactory(e.g.joint author
284、isation process to grant individual rights of use for radio spectrum,co-investment and wholesale only provisions had not been much used ������in practice).This is due not only to the delayed transposition by several Member States,but also because of the complexity of the framework and its procedures.While
285、 reinforcing i�����nvestment objectives,the Code also aims at promoting competition(both at infrastructure as well as at services level),contributing to the development of the internal market and promoting end-user benefits.The assumption is that competition dr�������ives investment based on market demand and i
286、s beneficial to consumers and businesses.All these principles remain valid but in addition due to recent technological developments and new global challenges,it should be considered whether incorporating wider dimensions such as sustainability,i������ndustrial competitiveness,and economic security into th
287、e policy framework,would be appropriate.Whatever measu��������res might be taken in the future to address said new challenges,end-users protection,including consumers,will continue to carry important weight among the objectives.Ultimately,the stable bedrock of any future regulation should be the“European De
288、claration on Digital Rights and Principles for the Digital Decade”of 15 December 2022,according to which people are at the centre of the digital transformation in the European Union and all businesses,including SMEs,should benefit from it.3.2.2.Scope of application������� In light of the developments descr
289、ibed above(see section 2.3.4),and in particular the quick progressing of convergence between electronic������ communications networks and cloud,a rethinking of the scope of application of������� the electronic communications regulatory framework could be considered.Currently,an end-user sends or receives data th
290、at“travel”via different networks or network segments(ranging e.g.from submarine cables to local access networks)and that are subject to different applicable rules.It is difficult to justify the rationale for such difference in the applicable rules(for instance,as regards lawful inte�������rception).At the
291、same time,the recent technological changes create an opportunity for alignment of the operations of electronic������� communications and cloud services with the development of pan-European core network operators.For example,the cloudification of 5G networks can provide ������significant benefits to the electroni
292、c communications network providers and allow them to leverage the same economies of scale of cloud providers by,inter alia,unifying the core ne������twork functionality of several national electronic communications networks in the����� cloud.However,when it comes to electronic communications networks,this inte
293、grat�������ion of functionalities in centralised cloud data centres that provide cross-border core network functionalities currently faces several legal barriers due to non-harmoni������sed legal frameworks in the Member States,inter alia,in the area of authorisation.26 On the service side,a consistent provision
294、 of NaaS-based app������lications relying on standalone 5G core networks,network slicing,and spectrum resources available across Member States could provide a new business case for cross-border operations.On the network side,it is to be recalle������d that-in contrast to voice traffic(which is billed according
295、to the calling partys net�����work pays principle)-IP interconnection currently appears to rely on transit and peering agreements usually based on a“bill-and-keep”approach where the Internet Service Provider(ISP)does not receive payments at��������� the wholesale level for terminating traffic.According to the mod
296、el generally attributed������� to the IP interconnection market,the ISP normally recovers its costs at the retail level by selling internet connectivity to its end-users,who generate internet traffic when retrieving data/content offered by CAPs.For supplementary paid peering and for transit,typically payme
297、nt is made on the basi�����s of the capacity provided at the point of interconnection.The main recent changes in the overall global architecture of the internet and of interconnecti�����on are caused and driven by the expansion of own backbone and delivery infrastructures by the CAPs.This has shifted the rela
298、tion of interconnection in the form of transit and peering70,with“on-net”exchange now predominating71,with the CDNs dedic������ated local storage servers(cache serve�������rs)collocated directly in the ISPs networks.This leads to a very direct and cooperative interaction between CAPs and ISPs as they have to agr
299、ee on technical and commercial conditions for transit and peering bilaterally(e.g.on the locations of traffic handover,the level of transit prices,on the question of settlement-free or paid peering or on������ quality and efficiency aspects).There are very few known cases of interve�������ntion(by a regulatory a
300、uthority or by a court�������)into the contractual relationships between market actors72,that generally functions well and so do the markets for transit and peering.There has been nonetheless a vivid debate on this topic73.Moreover,it cannot be excluded that the number of cases in the futu�����re will increase.
3�������01、Should this be the case,subject to careful assessment,policy measures could be envisaged to ensure swift resolution of disputes.For example,the commercial negotiations and agreements could possibly be further facilitated by providing for a specific timeline and by considering the possibility for req
302、uests for dispute resolution mechanisms,in case commercial agreements could not be found within a reasonable period of time.In such case,NRAs or(in cases with a cross-border dimension)BEREC could be solicited,as they have the nec�������essary technical knowledge,and important experience in dispute resoluti
303、on and in assessing market functioning.3.2.3.������Authorisati���on The general authorisation regime established in 2002 and maintained in the Code replaced the previous regime of individual licenses/authorisations,by pre-establishing generally applicable conditions for the provision of electronic communicat
304、ion networks and services(ECNS).Yet,given the local character of the p������hysical networks,and the fact that spectrum is deemed to be a 70 See e.g.WIK-consult:Final study report“Competitive conditions on transit and peering markets”,Bad Honnef,28.02.2022.71 Only a few ISPs do not allow on-net data excha
305、nge,continuing instead to exchange traffic across network boundaries and point of interconnection.72 For an overview of known cases see WIK-consult:Final study report“Competitive conditions on transit and p������eering markets”,Bad Honnef,28.02.2022.73 For an overview of the various arguments raised in th
306、is debate,see e.g.also the responses to the relevant section of the exploratory consultation available at https:/digital-strategy.ec.europa.��������eu/en/news/consultation-electronic-communications-high�����lights-need-reliable-and-resilient-connectivity.27 national resource(see section 3.2.5),authorisations are
307、 subject to conditions established by the Member States competent authorities and granted and implemented at nation�������al level.Nonetheless,due to cloudification and softwarisation,network provision is less and less linked to location.Furthermore,coverage of wireless networks,such as satellite networks,
308、can extend beyond national and even EU borders.While there are still clear benefits in keeping the implementation of authorisation regimes at national level,in particular for lo�����cal access and retail services,assigning radio spectrum under conditions which differ between Member States may not always
309、be the most efficient approach,in particula������r for satellite communications.There could therefore be an economic and technical justification for a more European approach.One of the elements explaining the fast development of information society services has been the fact that they could be provided to
310、 the entire EU simply by complying with the legislation of the Member State of establishment(so called country of origin principle),without the need �������������to comply with the legislation of each Member State in which services are provided.While network virtualisation may technically allow the provision of
311�������、cross-border core networks and create a market for core network services,the business case cannot develop if there is insufficient scale,or if different regulatory regimes hinder such business case.To develop the business case,setting out a single set of rules by enabling authorisation based on the
312、country of origin principle for providers of core networks and core network services could balance the ap������proach to all types of providers�� of digital networks and services,putting them on a more equal level.In the converging ecosystem,where a boundary between the“traditional”providers of digital netw
313、orks an�������d servic���es on the one hand and the providers of e.g.cloud services on the other hand becomes increasingly blurred,the regulatory treatment of those services should be more holistic.It could also lessen the administrative burden by bringing in potential rationalisation of reporting obligations
314、 of different actors.The application of a single set of rules based for instance on a country of origin principle for core networks and core network services would enable EU core network operators to leverage the full potential of the internal market to reac����h critical size,take adv������antage of scale ec
315、onomies,and reduce capital expenditure and operating costs,thus solidifying their financial position,attracting more private investments and ultimately contributing to EU competitiveness.In this scenario,the applicable������ legislation and the competent authority to regulate access to networks and retail
316、 serv�������ices provided to end-users would remain the same and the one closest to the end-users,i.e.those of the Member State of the provision of the access network and of the retail servi�������ce.This would also ensure that the specificities of local markets are adequately taken into account when defining app
317、ropriate access remedies and when guaranteeing the highest level of prot�������ection of end-users.3.2.4.Addressing barriers to core network centralisation In addition to the sector-specific regulatory barriers mentioned above,contributors to the exploratory consultati������on listed other regulatory barriers to
318、 the establishment of a true Digital Single Market such as different obligations across the EU with regard to n��������etwork/service incident reporting or security vetting requirements,building lawful interception capabilities,data retention regimes,privacy and reshoring requ�������irements or cybersecurity and r
319、eporting obligations74.74 The results of the exploratory consultation were published in Octobe�����r 2023 and are available at https:/digital-strategy.ec.europa.eu/en/news/consultation-electronic-communications-highlights-need-reliable-and-resilient-connectivity.For this specific point see page 12 under
320、point ii.Obstacles to the Digital Single Market.28 Having due regard to Member St����ates sovereignty as well as their competence on security issues,it is worth reflecting on whether and how those other barriers could be addressed to allow achieving scale and enhance innovation.For example,in relation t
321、o security incidents or security vetting to further improve harmonisation and a high level of security,different measures could be envisaged,such as introducing close cooperation between those Member States where a core network spans,guaranteeing core network operators ����the right to request all compe
322、tent authorities of the Member States in which they provide networks to agree on a set of conditions and requirements to be consistently applied through�����out the network and be verified at a one stop shop;defining security requirements for core network operators through EU level guidance etc.As regard
323、s law enforcement obligations such as lawful interception,one option could be that core network operators identify in each Member State where they operate a po����int of contact for competent national �������law enforcement authorities.Soft law measures,such as an EU recommendation or guidelines,could help ide
324、ntify and specify such solutions on security and l�����aw enforcement.3.2.5.Radio spectrum Spectrum plays a pivotal role in wireless connectivity and should be managed in the best coordinated way possible among all Member States t����o fulfil the Union objectives of sustainable development,balanced economic
325、growth,economic,social and territorial cohesion,and solidarity among Member States.Earlier attempts to establish greater EU coordination in spectrum management were not fully successful,and,in parallel,discrepancies and delay�������s have been obs������erved in authorising spectrum for 5G deployment across the M
326、ember States.As a consequence,today Europe is lagging behi�������nd its international competitors on the uptake of 5G.The observations in Section 2 indicate that there is scope to further improve spectrum policy across the EU and make spectrum management fit for the Digital Decade needs and targets.3.2.5.1
327、.Adapting spectrum management to Dig��������ital Decade needs:lessons learned from earlier legislative efforts A number of proposals by the European Commission to better harmonise the release and licensing of radio spectrum for mobile services have faced considerable resistance in the past 10 years.In view
328、of the del�������ays,fragmentation and in certain instances artificial scarcity that led to very high prices paid for spectrum,it is worth considering whether solutions that were proposed in earlier legislative efforts�����,but eventually not retained by the co-legislators,could have avoided some of the negativ
329、e effects that are now evident given the delayed 5G deployment.Considering the necessity to complete 5G roll-out and timely 6G deployment,a more cooperati���ve approach between the national and European level is of vital importance for EU competitiveness.In this context,areas that deserve to be conside
330、red and possibly lead to relevant actions include:(i)EU level planning of sufficient spectrum for future use cases,(ii)strengthening EU level coordination of auction timing,and(iii)considering more uniform spectrum authorisation landsca�����pe.No wireless service can be deployed without the avai����lability
331、of sufficient spectrum resources.This would include evolving and new areas such as ver�����tical use cases,6G,IoT applications,WiFi,local spectrum use.Also,this includes rapidly developing satellite communications,ensuring secure government and commercial applications,including direct-to-device satellite
332、 connectivity,using spectrum allo������������cated for mobile satellite and,if appropriate,terrestrial services.In this context it should be considered whether,to ensure that new technology advancements are rolled out across the EU at the same time,an EU spectrum roadmap towards 6G should be enshrined in the la
333、w and enforced in a coordinated way by all Member States.29 Coordinated release and refarming would be crucial in ������this context.Key example is the coordinated switch-off of 2G and 3G networks(with release of the relevant spectrum for other uses)while,in para����llel,implementing solutions for continuous support of important legacy services such as emergency and critical communications(e.g.eCall75).At t
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