2.1. Introduction

The virus SARS-CoV-2 and the associated disease COVID-19, which the WHO declared a pandemic on 11 March 2020, turned the world upside down, resulting in countries across the globe issuing various forms of stay-at-home social distancing rules and closing in-person economic activity in an effort to stem the spread of the disease (European Centre for Disease Prevention and Control, 2022; WHO, 2022). Where possible, virtual encounters replaced physical ones, and social, educational, and commercial activity increasingly moved online during the course of the lockdown and ongoing pandemic (at least for those activities that could shift online).¹ This dramatic shift had profound effects on our social and economic lives. Some will result in long-lasting changes, while others may be temporary crisis responses. Some of the effects and responses were anticipated, some are surprises, and others are evolving in real-time.

COVID-19 has disrupted the ‘real’ world and has substantial implications for the virtual world and thus the Internet ecosystem. It caused a significant exogenous shock that offers a wealth of natural experiments and produced new data about broadband, clouds, and the Internet in times of crisis and enables testing of established and proposed hypotheses about the resilience and adaptability of the ecosystem. These unparalleled research opportunities for observing the interaction effects between the real and virtual worlds provide novel possibilities to evaluate how well today’s communications networks, services, and applications have responded to the increased and changing traffic loads and assess the evolving responses by private actors such as ISPs and content and cloud providers as well as governments. The natural experiment(s) afforded will continue to be mined and analysed for network provisioning/management and policy insights in years to come.

In this chapter, we highlight emerging insights and explore the interaction effects between the real and virtual worlds. Our focus is on the USA and Europe and deriving lessons and insights into how we can better plan for the future post-COVID-19 ‘new normal’. Recognising the research potential of the ongoing crisis, we began collecting trade-press, blog posts, academic research, sundry white papers, and related materials that were publicly available and related to the performance and management of Internet infrastructure and services and user and policy responses as those evolved in real-time starting in the first quarter of 2020 when the extent, duration, and impact of the pandemic were uncertain. Our collection methods were not systematic but were informed by our long engagement in multidisciplinary research related to Internet technology, industry, and policy developments. The materials we collected numbered over 3,000 entries. Our initial review of these materials, presented here, focuses on identifying how the COVID-19 experience helps confirm what was known pre-COVID-19, what lessons are new, and what questions remain to be explored further.

The remainder of this chapter is structured as follows. In Section 2.2, we provide an overview of the effects of COVID-19 on Internet traffic and explore how well the Internet has coped with the new demands and where specific weaknesses were revealed. Section 2.3 highlights the responses by policy-makers and by industry. Section 2.4 discusses the impact of COVID-19 in light of those responses for the Internet ecosystem and the lessons we take from our evaluation. Section 2.5 briefly sums up and concludes.

2.2. The Effect of COVID-19 on Internet Traffic

The pandemic and the measures to contain the spread of the virus have fundamentally changed social and commercial activity. Unsurprisingly, it has caused sudden and unexpected increases and shifting patterns in Internet traffic and substantially changed usage patterns (Feldmann et al., 2020, 2021; Koeze & Popper, 2020; Labovitz, 2020a; OECD, 2020a, 2020b). One of the most significant changes relates to the location of Internet access as many individuals had to rely on their residential broadband connections to maintain their social and economic activity, for example, working, educating, and consuming entertainment from home. Moreover, many citizens changed locations, leaving city centers and (temporarily) moving to more rural or remote areas. The change of access point has emphasised the important role of residential broadband access and in-home networks (e.g. local home WiFi networks). Where these networks are not well-provisioned, rely on outdated hardware and software, or are not configured correctly, they can present performance bottlenecks that limit access to online services and a good-quality user experience. Additionally, the shift to at-home use led to a geographical dispersion of the access points from ‘aggregation points’ such as enterprise networks or university campus networks. Moreover, reduced mobility implied that even when mobile devices were used, they were often connected via local home WiFi networks, thus relieving mobile network traffic (Comcast, 2020; Feldmann et al., 2020; Lutu et al., 2020; Schlosser et al., 2020; The Economist, 2020; see also Apple, 2021²; Ritchie et al., 2022). Thus, the traffic that ISPs needed to carry shifted from originating at business locations to residential locations, with the attendant shift in the utilisation of the ‘first-hop’ access network facilities used to provision such activity. For example, the typical away-from-home access connection (e.g. office building, school, etc.) aggregates access traffic for many users (employees, students, etc.) before connecting it to wider-area networks off-site (whether those be the public Internet or private networks) via business-grade connections which are typically provisioned and tariffed differently from mass-market (residential) fixed or mobile broadband connections.

In addition, the change of access location has often been accompanied by a change in the access environment – for example, a workplace (or school) network environment optimised and specifically secured was replaced by local access from home and remote access via virtual private networks (VPNs) (Feldmann et al., 2021; World Bank, 2020). Because bricks and mortar retailing (see Whalley & Curwen, 2023, this volume) and other places like cinemas had to close during lockdown measures, offline entertainment and commercial activities like retail shopping, restaurants, gyms, and other offline activities migrated to the virtual sphere. The result of these shifts was higher traffic demands by residential broadband access users and shifts in usage and traffic patterns (e.g. Baumgartner, 2020; Cloudflare, 2021; Feldmann et al., 2020, 2021; Filipovic & Cervall, 2020; OpenVault, 2020a, 2020b, 2020c, 2020d; The Economist, 2020).

The changes noted above would not have been possible with the pre-2000 Internet where most users accessed the Internet over low-speed, intermittent dial-up modem connections. In such a world, the opportunity to shift economic activity online would have been much more severely constrained. The basic networking infrastructure for enabling connectivity, the devices, the applications, the software, and the digital services used by businesses and consumers were much less capable and ubiquitously in use than they were in the years immediately preceding the onset of the pandemic. Over the past decade, significant changes have occurred in the Internet ecosystem, with perhaps the most important change being the shift to generally available broadband Internet access services offering data rates measured in the 10s to 100s of Megabits per second or faster³ and the wide availability of end-user devices and supporting applications and software capable of real-time video-conferencing and other interactive, multimedia applications.

These evolutionary ecosystem changes set the stage for a shift from face-to-face physical interactions to virtual interactions for those with the right equipment, skills, networking infrastructure, and jobs. E-commerce also flourished, with growing shares of global commercial activity having moved online. A key demand driver for much of this investment was the growth in demand for over-the-top (OTT) video entertainment, and concurrently, growing demand for everywhere accessibility that fuelled simultaneous growth in streaming media (video and music services like YouTube, Netflix, and Spotify launched in 2005, 2007, and 2011, respectively) as well as real mobile broadband (e.g. smartphones after 2007 iPhone release and 4G LTE after 2010).

Accommodating these changes required significant investment and adjustments by network and service providers across the Internet ecosystem.⁴ In addition to the investment in more capable broadband last-mile infrastructure, the need to deliver the surge in video traffic propelled the rise of Content Delivery Networks (CDNs) that increasingly sought to deploy (highly) distributed serving infrastructures to cache content closer to end-users. Distributed cloud and serving infrastructures have brought networked computing resources closer to end-users. In addition, they reflect a cloudification process by which a growing share of traffic is delivered via cloud-based systems. On top of that, the rise and rapid growth of geographically distributed interconnection facilities expanded options for where networks can meet, directly interconnect, and exchange traffic (e.g. via so-called Internet Exchange Points (IXPs)). Consequently, these developments have contributed to significant changes in the topology of the Internet. The Internet has become flatter with fewer hops between communicating endpoints – for example, between end-users (human-to-human), smart devices (machine-to-machine), or an end-user and the server where the content is stored or data is processed (human-to-machine).⁵ Due to these pre-COVID-19 developments, the Internet was already well-positioned to handle the COVID-19 pandemic’s sudden and forced shift from physical to virtual economic and social activity in many advanced, broadband-capable markets as a consequence of having been investing heavily in prior years to address the double-digit annual growth rates in traffic that have characterised the Internet for the past decades.

2.2.2. Impact on Internet Traffic

Changing end-user and edge provider (e.g. application and content provider) usage patterns translate into changes in network traffic. They also imply changing requirements regarding network capacity and performance (e.g. in terms of reliability and latency, jitter, and packet loss rates). As we described above, the shift towards more virtual activities changed the locations from where, the timing for when, the selection of applications, and the modalities (e.g. type of device) online applications and services were used.⁷ These shifts resulted in commensurate shifts in network traffic, imposing strains on the ISP networks and ancillary service providers that connect end-users and application/content service providers.

Against the background of the sudden demand shifts caused unexpectedly by the pandemic, it is hardly surprising that in the early stages of the lockdown measures, concerns arose that the Internet might collapse from the need to rapidly adjust to shifting so much activity online in response to COVID-19-related mandates (e.g. Fleming, 2020; Watson, 2020). Although ISPs had grown accustomed to aggregate traffic growth on the order of 30% per year, in March 2020, many ISPs and other providers experienced such levels of growth over a few weeks (e.g. Feldmann et al., 2020). As collective experience has demonstrated, the Internet has not collapsed but instead coped rather well with the unexpected increases and shifts in traffic. Already by mid-2020, the Internet had weathered the storm of the first wave and had proven its critical role in enabling online activity to substitute for offline activities, and in so doing, contributed significantly to mitigating the substantial negative social and economic effects of the pandemic that otherwise would have occurred had the pandemic struck in a world with less-advanced Internet capabilities (e.g. Belson, 2020a; Heaven, 2020; Stocker & Whalley, 2021; Timberg, 2020). Digital infrastructures, in particular the Internet, provided a lifeline for many and contributed significantly to social and economic resilience during the crisis (e.g. Briglauer & Stocker, 2020;⁸ Cloudflare, 2021; Feldmann et al., 2020, 2021; Rexford, 2021). With the trend towards telecommuting and more flexible work/schooling options (with mixed onsite and remote work/education) becoming increasingly prevalent, especially as the pandemic continues to cause restrictions that require the adoption of such options, COVID-19 has provided a significant step-change boost in support for and efforts to improve the robustness and capabilities of our broadband networks. In 2022, the question now is where the future post-COVID new normal will be and how will employers and schools adjust when onsite and in-person operations become increasingly acceptable.

A series of studies and reports have investigated the stability, resilience, and adaptability of the Internet during the pandemic. Whereas many of these reports and studies had been motivated by the initial impact of the first wave and lockdowns across different countries and the sudden changes these have caused, some also covered the effects of subsequent waves and lockdown measures. Appendix 2.1 provides an overview of some of these studies and reports.

2.2.2.1. Internet Traffic and Network Performance – A Tale of Aggregates, Peaks, and Troughs

To understand the pandemic’s impact on Internet traffic and network performance, it is important to understand the extent to which peak traffic and network utilisations change. As mentioned above and as shown in several studies, overall Internet traffic increased by 25–30% within a few couple of weeks and thus by as much as it would normally increase within an entire year (FCC, 2020b; Feldmann et al., 2020; Leighton, 2020b).⁹ This level of aggregate increase in demand in a few short weeks represents a significant demand shock that would stress many industries, and so for those not familiar with how networks are provisioned, it is hardly surprising that some feared the increased traffic might result in serious disruptions and degradation in Internet performance (Fleming, 2020; Timberg, 2020). However, the Internet has lived with double-digit annual aggregate (and per-average-user) traffic growth for several decades (e.g. Cisco, 2020) so the challenge for well-provisioned ISPs was to accommodate a year’s worth of growth in a few weeks – difficult, but not infeasible. Similar levels of traffic growth as were experienced by access provider ISPs were experienced by transit providers, cloud and content providers, and at IXPs (e.g. BITAG, 2021; Davidson, 2020; OECD, 2020a).

In provisioning networks, capacity is added in lumpy increments in advance of projected demand growth. The reference point for upgrade decisions is oriented at traffic peaks and peak utilisation levels since this indicates network congestion. To address the unexpected COVID-19-related traffic spikes and to maintain high customer experience levels, ISPs needed to pull forward their annual capital spending and provisioning work by a number of months to allow them to accommodate the growth in traffic peaks (e.g. Liu et al., 2021).

Whereas changes in peak traffic and peak utilisation are critical in assessing the impact on Internet performance, it is worthwhile to note that (i) decisions on capacity upgrades are based on expected growth in traffic peaks since these critically determine the stability and performance of network operations during peak demands and thus customer experience; and (ii) that providing for excess capacity during the peak to accommodate normal fluctuations in traffic is a standard operating procedure. However, the amount of excess peak capacity that is provisioned must be balanced with economic considerations. That is, too much excess capacity for unexpected peaks results in over-provisioning, excessively low average utilisation, and equivalently, high average costs and is – at least in normal times when average yearly growth rates are rather predictable at about 25 to 30% – economically inefficient.

The fact that aggregate traffic growth alone does not give insights into the (potential) impact of the pandemic on network performance can be illustrated by a simple example. Suppose all traffic growth would have been in off-peak hours, that is, in pre-COVID-19 traffic troughs when network utilisation was very low anyway. In such a case, large traffic growths may not even require additional capacity investment. So, the questions to ask are when did the major increase in traffic occur and how have traffic peaks changed?

In fact, much of the traffic increase occurred during off-peak periods (i.e. filling in pre-COVID-19 troughs).¹⁰ Thus, the strain on ISP capacity was significantly easier to accommodate than if aggregate increases had occurred at the peaks and been accommodated with a per-period usage profile mirroring pre-COVID-19 usage profiles. Peak period traffic did increase, arguably to varying extents in different networks and geographies (see Fig. 2.1 and Table 2.2 below). While Feldmann et al. (2020, 2021) reported that peak traffic growth was much less than the 30% that was experienced in aggregate traffic for the (representative) set of vantage points they analysed, Labovitz (2020a) reports an increase of 25–30% in global peak Internet traffic. When comparing data on peak traffic changes, it is important to note that definitions of peak traffic and measurement techniques may vary across different measurement studies, thus rendering comparisons difficult. While Feldmann et al. (2020, 2021) consider peaks as an average based on an hourly or daily basis, other studies like those of Liu et al. (2021) or Labovitz (2020a) use more short-term measures.¹¹

Had traffic peak increases been on the order of 60% or well above that would likely have resulted in much more significant disruptions since that level of demand growth is out-of-scope for reasonable planning efforts.¹² Had traffic peaks grown by that amount or more, ISPs would probably have needed to be (more aggressive in) adopting their traffic management strategies and throttle or reduce the data throughput or rate for traffic that is deemed ‘less important’ (e.g. pure entertainment content like video streaming) to ensure high service availability and customer experience for essential online services (e.g. those related to remote work or education). The fact that ISPs have the decision authority upon relevant prioritisations is also presumably why, for example, BEREC (2020) provided some policy guidance on what traffic management practices would be acceptable during exceptional circumstances in the pandemic (see Section 2.3.1).¹³

2.2.2.2. How Traffic Patterns Have Changed

Apart from traffic increases, the pandemic has caused changes in traffic patterns. While traffic patterns pre-COVID-19 were characterised by peaks and troughs, especially during weekdays, social distancing and lockdowns have changed this. Importantly, although peaks were higher, it is also the case that traffic is spread out more evenly throughout the day. That is, previous troughs have been partially filled in. Whereas traffic peaks have slightly shifted, traffic patterns on weekdays have converged to those that previously characterised weekends (Feldmann et al., 2020; SamKnows, 2020a; Sandvine, 2020; Stocker & Whalley, 2021). For example, there has been a considerable increase in traffic levels during the daytime as network users adapted to new COVID-19 lifestyles, mixing online playtime and worktime to correspond more to at-home schedules than the traditional at-work-during-the-day/at-home-at-night scheduling that prevailed pre-COVID-19. Work, education, entertainment, and maintaining social contacts were shifted as much as possible to the virtual sphere. Not only did the patterns in Internet usage by time-of-day/day-of-week change due to COVID-19, but so too did the application mix and application usage in general, both in terms of intensity as well as in terms of structure. Finally, changing traffic matrices imply changes in interconnection traffic and the changing application mix manifests itself in changing downstream-to-upstream traffic ratios (e.g. Feldmann et al., 2020; OpenVault, 2020a, 2020b).

2.2.2.3. Summary and (Tentative) Outlook – The Future Course of the Pandemic Effect

The findings summarised above have been largely confirmed by a series of publications. Appendix 2.1 provides an overview and brief characterisation of some important reports and articles. Whereas different actors in the ecosystem have managed to weather the pandemic-related storm, within-group experiences (e.g. among ISPs, IXPs, or CDNs) varied significantly. Additionally, the effects of the pandemic on Internet traffic, network utilisation and congestion, as well as on customer experience, have varied locally. Fig. 2.1 and Tables 2.2a and 2.2b provide representative examples of traffic changes during the pandemic as experienced from different vantage points and by different actors.

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Fig. 2.1.

Annual Changes in Cross-country Internet Traffic.

Table 2.2a.

Examples of Changes in Internet Traffic (by Region).

Where? (What?)	Metric	Change (Time Period; Location/Networka)	Source
Global	Global Peak Internet Traffic	+25–30% (May 2020 vs. First Week of Feb. 2020)	Labovitz (2020b)
	Global Internet Traffic	+25% (May 2020 vs. First Week of Feb. 2020)
	Global Internet Traffic	+38% (19 Apr. 2020 vs. 1 Feb. 2020)	Sandvine (2020)
	Global Upstream Traffic	+121% (19 Apr. 2020 vs. 1 Feb. 2020)
	Global Downstream Traffic	+23% (19 Apr. 2020 vs. 1 Feb. 2020)
	Global Internet Traffic	ca. +30% (Mar. 2020 to Apr. 2020; Akamai CDN)	Leighton (2020b)
Other	Aggregate Traffic	ca. +20–30% (Mar. 2020 to Apr. 2020; First lockdowns in Europe)b	Feldmann et al. (2021)
	Downstream-to-upstream Traffic Ratio	18% Relative Increase in Upstream Traffic; Ratio changes from ca. 9:1 (Pre-covid) to 8:1 (Early 2021) (Weekdays)b
Different Countries (CDN)	Traffic Change (Italy)	+109.3% (31 Mar. 2020 vs. 20 Feb. 2020; Fastly)	Bergman and Iyengar (2020)
	Traffic Change (Japan)	+31.5% (31 Mar. 2020 vs. 18 Feb. 2020; Fastly)
	Traffic Change (UK)	+78.6% (31 Mar. 2020 vs. 27 Feb. 2020; Fastly)
	Traffic Change (France)	+38.4% (31 Mar. 2020 vs. 26 Feb. 2020; Fastly)
	Traffic Change (Spain)	+39.4% (31 Mar. 2020 vs. 1 Mar. 2020; Fastly)
	Traffic Change (NY & NJ, USA)	+44.6% (31 Mar. 2020 vs. 1 Mar. 2020; Fastly)
	Traffic Change (CA, USA)	+46.5% (31 Mar. 2020 vs. 1 Mar. 2020; Fastly)
	Traffic Change (MI, USA)	+37.9% (31 Mar. 2020 vs. 1 Mar. 2020; Fastly)

Table 2.2b.

Examples of Changes in Internet Traffic (by Provider).

Category	Provider(s)	Change (Time Period; Location/Networka)	Source
Communications Service Providers	Cable ISPs in the USA	+20.1% Downstream Peak Traffic (28 Mar. 2020 vs. 3 Jan. 2020; USA)	NCTA (2021)
		+27.7% Upstream Peak Traffic (28 Mar. 2020 vs. 3 Jan. 2020; USA)
	Comcast	+32% Peak Traffic (Compared to pre-pandemic levels)	Comcast (2021)
		+38% Downstream Peak Traffic (compared to 2019 levels)
		+56% Upstream Peak Traffic (compared to 2019 levels)
	Verizon	+30% Web Traffic Peak Usage (22 Apr. 2020 vs. Typical pre-pandemic day)	Verizon (2020)
		+24% Web Traffic [Peak Usage] (2 Apr. 2020 vs. Typical pre-pandemic day)c
	NTT Communications	+30–40% Internet Traffic [weekdays between 9 a.m. and 6 p.m.] (Mar. 2020; Japan)	NHK (2020)
	Telefonica	+35% Fixed Data Traffic (mid-Apr. 2020 vs. mid-Mar. 2020)	Robuck (2020)
	Telia Carrier	>+50% Overall Traffic (begin of pandemic until mid-Apr. 2020)	Robuck (2020)
	BT	+35–60% Weekday Daytime Traffic (20 Mar. 2020 vs. 17 Mar. 2020)	Watson (2020)d
	AT&T	+40% Daily Network Traffic (Year-on-year: 2020–2021; Average day)	Chow and Mair (2021)
		+22% Core Network Traffic (30 Apr. 2020 vs. End of Feb. 2020)	AT&T (2021)e
		+25% Core Network Traffic (17 Apr. 2020 vs. End of Feb. 2020)
		+24% Core Network Traffic (7 Apr. 2020 vs. End of Feb. 2020)
	Vodafone	>+50% Fixed Broadband Usage (ca. 3 Apr. 2020 vs. Pre-pandemic levels; Italy & Spain)	Vodafone (2020a)
		+100% Upstream Traffic (ca. 3 Apr. 2020 vs. Pre-pandemic levels; in some markets)
		+44% Aggregate Downstream Traffic (ca. 3 Apr. 2020 vs. Pre-pandemic levels)
Internet Exchange Points (IXPs)	DE-CIX	>+10% Peak Traffic (June 2020 vs. Pre-pandemic Levels; IXP in Frankfurt)	Dietzel (2020)
		>+20% Peak Traffic (June 2020 vs. Pre-pandemic levels; IXP in Düsseldorf)
	AMS-IX	+17% Traffic Volume (22 Mar. 2020 vs. Previous Month; Amsterdam)	AMS-IX (2020)
		+35% Total Data Traffic (2020, annual; Amsterdam)	AMS-IX (2021)

Notes for Tables 2.2a and 2.2b: The numbers presented here, even if they refer to global traffic changes, are based on measurements from different vantage points and may involve extrapolations. To provide a more complete picture, we chose to provide measurements from different providers, regions, and vantage points. However, we want to emphasise that results (and measurement techniques) may differ between different (types of) companies and networks, regions, and the scope considered both in terms of geography and actors.

^aInformation only provided if deviating from the overall footprint of the provider.

^bFeldmann et al. utilise data from a set of vantage points: one large European ISP which operates a Tier-1 network, three IXPs (a major IXP in Central Europe; an IXP in Southern Europe; and an IXP at the US East Coast), and one metropolitan educational network (REDImadrid).

^cThe data provided for 2 April do not explicitly state that it is about peak usage but those provided for 22 April do. It is to be assumed that both refer to peak usage.

^dWatson, Chief Technology and Information Officer at BT, states: “Since Tuesday this week, as people started to work from home more extensively, we’ve seen weekday daytime traffic increase 35–60% compared with similar days on the fixed network, peaking at 7.5Tb/s. This is still only around half the average evening peak, and nowhere near the 17.5 Tb/s we have proved the network can handle.” (Watson, 2020)

^eCore network traffic comprises “business, home broadband and wireless usage” (AT&T, 2021).

In spite of anecdotal evidence of local problems and the existence of short-lived or transient congestion issues or failures – for example, websites crashed (e.g. unemployment benefit sites hosted by some agencies in the United States [Riley, 2020]) and other localised network and application disruptions occurred – the publications we analysed widely support the conclusion that the Internet coped well with the pandemic (see Appendix 2.1 and also, e.g., Böttger et al., 2020; Clark, 2020; Fontugne et al., 2020; Medina, 2020; S. Miller, 2020; ThousandEyes, 2020; Warren, 2020). Apart from the fact that one cannot unambiguously infer from a measured state of network congestion that this has caused or materialised a degradation in customer experience (Clark, 2020), persistent states of congestion and corresponding performance problems over the course of the pandemic or longer stretches of time since the first wave have not been reported in the publications we analysed.¹⁴ Quite to the contrary, the research has emphasised the Internet’s resilience and ability to adapt and failed to reveal any systemic structural problems.

Before we move on to explore the responses by private and public actors and investigate their strategies to weather the pandemic effects in the next section, it is worth looking ahead. Although the unexpected demand shock associated with the pandemic resulted in an unprecedented growth in traffic over a short time period, experts expected traffic growth rates to return in 2021 and subsequent years to pre-pandemic levels (e.g. Mauldin, 2021; Munson, 2021a, 2021b; Sangani, 2020; TeleGeography, 2021).

Data gathered by the Body of European Regulators for Electronic Communications (BEREC) in their various Reports on the status of internet capacity during coronavirus confinement measures (BEREC, 2021a) supports this conclusion. For example, in their summary report from 25 June 2021, BEREC identified three phases of how the pandemic affected Internet traffic: “a sharp increase in its early weeks, a subsequent stabilisation and, through the latter part of 2020 and 2021 thus far, a decrease from the peak (experienced early in the crisis)” (BEREC, 2021b, p. 2). In their summary report from November 29, they state:

In general, while traffic on fixed and mobile networks have increased during the (approximate) twenty months of the COVID-19 crisis, no major congestion issues have ever been reported by NRAs to BEREC. (BEREC, 2021c, p. 1)

2.3. Government and Private Sector Responses

Policy-makers and industry responded to the crisis in a variety of ways, mostly uncoordinated in time and choice of response as the crisis spread unevenly across countries. Both sought to implement strategies to facilitate the successful migration of activities to the virtual sphere to enable the continuation of economic and social activities disrupted by the stay-at-home and business lockdowns and operating restriction mandates and resulting health crises posed by the pandemic. Despite the lack of coordination, the availability and performance of online services that run over the Internet during the pandemic were not severely affected. Nevertheless, substantial digital divide and inclusion failures arose (or were highlighted in sharpened relief) as a result of the crisis and the uneven effectiveness and reach of the remedial actions taken (e.g. Bronzino et al., 2021; Gross, 2020; OECD, 2020b; Schilirò, 2021). Those problems were evident in both the European Union (EU) (e.g. ITU, 2021; Sostero et al., 2020) and the USA (e.g. Lai & Widmar, 2020; Vogels, 2021). While the term ‘homework gap’ (Basu, 2020) coined by then-FCC¹⁵ Commissioner Jessica Rosenworcel gained prominence, the United Nations stated that “[t]he digital divide is the new face of inequality in the COVID-19 era” (Bozkir, 2021, p. 3).

In the following, we will provide a brief and selective overview of the measures taken by public and private actors to respond to the crisis.

2.4. Collective Insights for a Post-COVID-19 Future

Clearly, the crisis played a dual role as an impulse and catalyst for investment and innovation and a change agent that promoted a step-change increase in efforts to advance the progress of digitalisation of our networking infrastructure, and digital economy activity. The resulting advances and changes are profound. They expand greatly the opportunity space for use and service innovation and at the same time are changing social and economic dynamics. Also, interactions and dynamics between the real and virtual worlds have changed during the pandemic. More specifically, lockdowns, social distancing, and other measures to contain the spread of the virus have impacted the real world and the virtual world. Real-world changes spur innovation in the virtual world. The virtual world, in turn, provides (partial) substitutes for actions, tasks, and processes of the physical world. These, in turn, might feedback on the real world. These interdependent dynamics and interactions create new realities, most notably perhaps, in that physical activity or interactions can be partly or entirely shifted online, thus facilitating new modes of living and work during the pandemic and also paving the way for a future post-COVID-19 world characterised by more online interaction and more hybrid/remote work and education, broad online-based social and commercial innovation and new offers in the virtual sphere.

When comparing the pre-COVID-19 Internet with the ecosystem we can observe today, we can identify a set of changes related to the spheres of networks and online services. Even though much of this may be temporary and has been spurred by an external shock, we do not expect the post-COVID-19 Internet ecosystem to return to pre-COVID-19 standards. Some of the changes and adaptations to enabling the virtual sphere to accommodate the changing demands will likely become integral to future societies and economies, and thereby become the ‘new normal’ (e.g. BCG, 2021). Other lessons learned may be temporary but become part of our toolset for responding to future crises.

In other words, some of the changes will be permanent and systematically change not only the virtual sphere but also the real world, for example, in terms of education, work, entertainment, and social interaction, as well as health services. However, the interplay between real world and virtual world effects is determined by the degree of transferability of activities, that is, the extent to which virtual (partial or full) substitutes exist or can be created (see, e.g., Pérez et al., 2020). While the degree of transferability to the virtual sphere varies quite significantly across different activities, it is fair to say that ‘structural’ problems associated with certain occupations or activities (e.g. workers doing physical labour often cannot stay at home and do their jobs remotely) or the lack of connectivity, adequate devices, or skill and knowledge to leverage the connectivity and digital technologies that exist create barriers, exclusion, and divides.²⁸

As of mid-2022, we continue to be in the midst of the crisis so the lessons we might learn of relevance to a future post-COVID-19 world need to be speculative at this time. Nevertheless, certain effects appear likely to be enduring. For example, the COVID-19 pandemic has nurtured digital innovation and efforts by private and public entities to foster digital transformation processes. While the changing realities of the physical world boosted innovation in the virtual world, the crisis increased the criticality and emphasised the essentiality of broadband and digital infrastructures.

With this in mind, there are two main high-level insights. First, the Internet has coped quite well with the pandemic. In previous sections, we have explained what changes have occurred and how the responses by private and public actors have helped to weather the unexpected demand shock. Second, while broadband has become essential for individuals and businesses, the Internet could only provide a lifeline and cushion the negative social and economic effects of the pandemic for those with adequate connectivity, devices, and the necessary skills to access the widening range of offers in the virtual. Thus, an important lesson learned from COVID-19 is the importance of a public commitment to ensuring universal access to broadband and support for cloud services as critical infrastructure to enable the digital economy to adapt and respond to future crises. In the same vein, complementary measures to support participation and digital inclusion are essential to reap the benefits of those infrastructures.

In the following, we will briefly summarise and discuss in more detail six lessons learned for the Internet.

• #1: The future is (more) digital – Beware of digital divides and support inclusion

As other chapters in this book explain for different sectors, the pre-pandemic commercial sphere as well as work and social norms will be different in a ‘new normal’. We anticipate changing usage habits and embedding more/new online services in the workplace, education, commerce, etc. (hybrid offline/online forms as the new default). This will change the innovation and competitive dynamics between and within offline and online services.

Not only is access to adequate and affordable connectivity a problem in certain regions and for certain parts of the population, but the lack of devices and also of skills may also interfere with individuals’ ability to take advantage of online services. In addition, it should not be forgotten that only some fraction of jobs and activity can be migrated to the virtual world, thus creating a fundamental source of future divides. Such barriers constrain the ability to exploit the potentials of the virtual world, thus also impacting the degree to which the negative effects of future crises can be cushioned, and social and economic resilience be maintained. Digital divides must be recognised in all their dimensions (infrastructural, skills, and literacy), and tackled by appropriate, comprehensive measures. New forms of divides may emerge due to differences in the transferability or migratability of activities or tasks to the virtual sphere – some may be easily transferable while others can only partially be migrated and others not at all (e.g. Stocker & Whalley, 2021; see also Bai et al., 2021).

Even though entrepreneurial innovation in the private sector is important to create solutions to facilitate participation and digital inclusion, it cannot fully resolve the multifaceted divides that have occurred at various levels. Government action via suitable policies and subsidy schemes may be needed; and during the crisis, relaxing non-crisis regulatory frameworks may be called for to give network providers the flexibility they need to respond quickly to rapidly changing needs. Governments may improve participation and inclusion by supporting access to adequate and affordable broadband connectivity. Notably, the US approach via the IIJA has added a quality component (i.e. the ability to “support real-time, interactive applications” [pp. 1182 and 1183]) to the static data rate criteria of 100 Mbps downstream and 20 Mbps upstream for an underserved location, and 25 Mbps downstream and 3 Mbps upstream for an unserved location respectively. In the EU, Appendix V of Directive (EU) 2018/1972 specifies a dynamised universal service objective for adequate broadband Internet access services which must be able to support the delivery of a pre-specified set of desirable/essential online services and activities – including video calls in standard definition and online tools for remote learning (e.g. Briglauer & Stocker, 2020). With its 2030 Digital Decade targets (EC, 2021), the EU has introduced much more ambitious targets regarding aspects like connectivity in terms of gigabit access and 5G coverage, but also regarding skills and other aspects (see also Section 2.3.1.1).

While the universal service measures focus on the availability of adequate access infrastructures and affordable connectivity services, additional measures are required to prevent digital exclusion (e.g. due to a lack of access to devices or skills to use the devices or take advantage of the range of online services). Apart from these measures, governments may want to consider supporting entrepreneurial efforts to invent and develop solutions and services that can reduce the fragility of societies and economies in times of crisis and enhance resilience.

• #2: The crisis has boosted investment and innovation

The crisis played a dual role as an impulse and catalyst of investment and innovation. The resulting advances and changes are profound. They expand greatly the opportunity space for use and service innovation and at the same time are changing social and economic dynamics. Non-orchestrated investments and innovation have produced an outcome that was not characterised by network islands or other forms of fragmentation as could have been feared in scenarios in which different, and perhaps competing, entities have to invest and innovate while being jointly involved in service provision. As we can observe today, the first wave arguably had the most significant impact on boosting innovation and investment, and generally in triggering responses to enhance the toolkit available to weather the pandemic effects on the Internet, societies, and economies, and to provide the capabilities needed in a future post-COVID-19 world.

• #3: The crisis has accelerated networking trends and made the ecosystem more robust and adaptive

The pandemic has accelerated networking trends, changed the topology of the Internet and the underlying connectivity fabric, and made the ecosystem more robust and adaptive. Much of the resilience was due to the ability to scale and elastically provide cloud-based services. Expansion of server capacity and interconnection/bandwidth capacity could be achieved rather quickly so that no systematic problems with application functionality or customer experience have occurred. Instead, capacity-on-demand has emerged as a vital enabler of elastic service provision and thus networking resilience and adaptability. Topological responses are here to stay; large cloud and content providers have invested in and upgraded their infrastructures and adopted hybrid models involving public cloud capacities to better scale to unexpected bursts. Moreover, peering diversity and adaptations in peering strategies were facilitated by IXPs and other interconnection strategies.

Updates were required to respond to a mismatch between traffic demands and matrices and pre-COVID-19 capacities and serving and peering strategies. ISPs updated their internal routing and link provisioning; this involved capacity expansion in their networks and adaptations in peering capacities and strategies (i.e. more direct and local peering) (e.g. Verizon, 2020). To some extent, this was also true for cloud and content providers, as the examples of Netflix and Dropbox suggest. CDN provider Cloudflare recently announced that they now connect directly to more than 10,000 networks. This means that they can reach more than 14% of the networks (i.e. autonomous systems, ASes) of the Internet – and thus probably a large majority of connected end-users – within a single network hop (Takami, 2021).²⁹ Whereas these developments have all contributed to a less fragile and more resilient ecosystem during the pandemic, they have accelerated or amplified pre-pandemic trends of cloudification, a denser and flattening interconnection ecosystem, and the localisation of networked computing resources and network traffic (see, e.g., Stocker et al., 2021). Respective topological changes are permanent.

The pre-pandemic progress in cloudification helped provide the infrastructural and technological basis and capacity to allow providers to quickly adapt to the changing demands. The pandemic showed that the immediacy and extent to which capacities had to be scaled up resulted in many cases of a relative shift towards the public cloud, where fast adaptations were possible (see, e.g., Labovitz, 2020a). Despite this ability to scale up and adapt quickly, Gigis et al. (2021) have shown that hypergiants like Netflix have adapted their serving infrastructures and tremendously expanded their footprints (i.e. their presence within ASes in which they have deployed off-net servers) (see also Section 2.3.2). These enhancements to their networks imply permanent topological changes and suggest they have adopted such provisioning strategies as their preferred response to future similar events. For example, Gigis et al. (2021) show that in April 2021, Google’s footprint allowed them to reach 77.5% of the European user population and 70.6% of the user population in North America via their off-net serving infrastructure.³⁰ In other words, cloud-based or hybrid cloud strategies might be preferred as short-term responses since they allow providers to quickly adapt and scale in response to rapidly changing demand. In the medium or longer-term, however, off-net (zero-hop) strategies seem to be preferred by many hypergiants like Google, Facebook, or Netflix. The expansion in these capacities suggests that these providers anticipate that the new normal for demand will continue to reflect the higher demand levels first experienced during the pandemic.

Over the last couple of years, the growth in IXPs and other distributed interconnection facilities has facilitated more local and direct peerings, thus making the interconnection ecosystem denser and flatter. On the one hand, these interconnection facilities have provided places for networks to meet and exchange traffic close to their customers/end-users, thus facilitating the establishment of direct and local peerings. On the other hand, these facilities typically have significant spare capacity that can be used in case of unexpected events. Moreover, they have ways to rapidly expand, adjust and allocate capacities (Dietzel, 2020; Feldmann et al., 2020).³¹ Thus, they were able to rapidly establish and accommodate the demands that arose due to new or upgraded interconnections and capacity requests.

• #4: The future of networking is more adaptive and agile

The delivery of a lot of entertainment content as well as real-time communications services like video conferencing is based on algorithms that enable adaptive sending rates and thus network usage that is responsive to the current network situation. Since large shares of traffic are already delivered in this way (e.g. Labovitz, 2019), the Internet has acquired the ability to resiliently cope with sudden increases in traffic and to manage, mitigate or avoid congestion. Since these capabilities are deeply engrained in today’s ecosystem, the necessity of the measures taken by commissioner Breton (see Section 2.2) have been scrutinised and called into question (e.g. Castor, 2020; see also Briglauer & Stocker, 2020). Besides the server-sided ability to dynamically adapt sending rates according to the current network situation, automation arguably helped a lot to quickly and efficiently upgrade and scale capacities both at IXPs as well as in networks and data centres. Furthermore, technologies and innovations based on softwarisation and virtualisation of network resources enhance the general agility and adaptability of networks and data centres, that is, how networks are managed, traffic is routed, and resources are allocated. This agility creates more flexibility and facilitates real-time adaptations to sudden changes in demands. Moreover, the use of AI/ML has enhanced the ability of many providers to rapidly adjust to changing demands. Finally, such technological advances have been accompanied by a trend towards more contractual flexibility. Contracts are becoming increasingly customisable and short term.

• #5: Home networks may emerge as performance bottlenecks.

Whereas networks have coped rather well with the unexpected shifts in demands, it could well be that the more intense use by multiple users (Sandvine, 2020, p. 5) has caused problems within home networks, thus turning them into performance bottlenecks. This can result from too much simultaneous at-home usage (relative to the broadband access service that the household subscribes to) or from misconfigured or inadequate in-the-home network capacity. These may account for the degraded performance as measured by those speed tests performed by end-users (e.g. BITAG, 2021). Service providers have only limited ability to control such ‘user-initiated’ congestion, but it does highlight the importance of addressing potential congestion bottlenecks along the end-to-end path that traffic needs to traverse and use a range of approaches appropriate to each element. For example, providing end-customers with better tools to track/monitor their usage may enable end-customers to better match their usage to the service subscription tier that is appropriate to their needs and to better identify congestion sources downstream from the provider’s access service (e.g. misconfigured WiFi networks or outdated hardware or software in the home).³²

• #6: The crisis emphasised the role of (publicly available) data

The pandemic has changed attitudes towards the management of privacy and cybersecurity in light of the increased need and capacity for localised/granular traffic/usage management. It has also given rise to an unprecedented wealth of publicly available data, providing new insights into the state of ecosystem evolution, online service usage, and the Internet’s ability to accommodate them. These data have informed a growing number of analyses and studies which have and will continue to contribute to a more nuanced understanding of the ecosystem, its strengths and weaknesses, and the factors determining its robustness and resilience. An important finding is that the pandemic has proven the value and need for a continuous and transparent measurement ecosystem. On the one hand, the data and insights into the state of networks during the pandemic were published by different (perhaps competing) private and public actors/stakeholders. On the other hand, measurements are based on differing techniques, vantage points, geographical scope, and aggregation levels. They may also rely on different terminology or concepts (e.g. the definition of peak or average traffic varies considerably). Whereas measurements were highly valuable for optimising responses (e.g. network provisioning and management) of different actors, inferring unanimous observations and comparing insights across the publicly available data thus turns out to be a challenging task.

Especially during the early stages of the pandemic, when concerns regarding the need to track the progress of the pandemic on a local and rapidly dynamic level and regarding the need to accommodate the rapid shift to online for work, education, and entertainment, service providers shared quite detailed location/time/device-specific usage data. At the same time, software developers strove to deliver mobile device-capable applications that could collect and share user-specific data that could contribute to COVID-19 tracing and network provisioning efforts. Were it not for the emergency situation, it is unlikely that such granular information would have been shared so freely. In normal times (i.e. in times in which no external shock is forcing activity to move online), such data is highly valued for its market research potential and is costly to acquire; and concerns about protecting user privacy and commercial confidentiality interests would have impeded the collection and sharing of the data. How this will impact user attitudes towards privacy and data security, commercial practices, application designs, and privacy/security policies in the future remains to be seen. In the meantime, one can observe that both public and private actors have reduced or even stopped providing detailed (real-time) information about the state of their networks. For example, Verizon stopped its reporting in November 2020.

2.5. Conclusion

About two years after the first lockdown measures were introduced in the USA and EU, the Internet ecosystem has coped quite well with the sudden and unexpected changes in demand and traffic patterns. Although local and transient problems have occurred (e.g. outages, congestion, or other service quality problems), the networks and services have proved to be relatively resilient, and the customer experience has generally been good. It seems fair to say that the pandemic has served to coalesce broad consensus regarding the conclusion that broadband digital infrastructures are essential facilities for economies, and are necessary for societal and economic participation, growth, and innovation. This was especially true and obvious during the pandemic, but remains true under normal, post-pandemic circumstances as well. To ensure that national communications infrastructures are up to the challenge, policy-makers in the EU and the USA have implemented a range of measures to tackle digital divides and support digital inclusion. Although the enhancement of broadband and related digital infrastructures had been progressing prior to the pandemic, the pandemic accelerated and catalysed digital transformation processes driven by private and public decision-makers.

In hindsight, most of what we observed after the initial shock was to be expected. Put differently, those familiar with the technical and market details regarding the state of content and service delivery, clouds, and interconnection in the pre-Covid Internet ecosystem had largely anticipated what would be needed as early as April 2020. Thus, they were able to accelerate planned responses rather than being forced to respond to wholly new circumstances. What COVID-19 helped do was bring the forecasted Internet future forward in time and convince non-experts of that need. As our chapter has demonstrated, the pandemic has acted as a change agent, not a game changer. That being said, it selectively changed the game for some services and arguably ignited and fuelled the rise and growth of new online services and platforms. For example, the success story of Zoom has been driven by the circumstances caused by the pandemic (BBC, 2021) and the timing of the launch of Disney+ in many countries in March 2020 arguably helped its initial success and growth (Faughnder, 2020). More generally, the pandemic has fuelled, accelerated, and amplified networking trends such as developments towards a denser and flatter interconnection ecosystem but also the cloudification and the growing role of highly distributed (intra-AS and off-net) serving infrastructures for expanding the footprint of hypergiants. Importantly, adaptations to the new demands have resulted in more localised networked computing resources and network traffic.

Resilience is a key capability for communications networks and server infrastructures. A few learnings can be derived. First, whereas connectivity providers (e.g. ISPs and MNOs) and cloud and content providers should (continue to) provision their infrastructures for traffic/demand peaks and have some excess capacity and headroom, changing traffic matrices have led to adaptations in the operations, management, and peering strategies of both communications service providers and cloud and content providers. The ability to rapidly scale up and reconfigure networks and capacities as well as peering strategies is important to achieve resilience and maintain high levels of customer experience. Second, entertainment content is (still) dominating the Internet. Most service provision is adaptable (e.g. via adaptive bit rates) and thus able to mitigate network overloads. While lowering data rates of such applications or rescheduling the delivery of static (bulk) content helps relieve strain in the short term, traffic management within networks can also play an important role in maintaining high levels of customer experience for the relevant range of services delivered. Third, automation has played an essential role in upgrading and scaling capacities and thus in addressing the mismatch between the pre-pandemic status quo and changing usage patterns and subsequent demand structures, requirements, and traffic matrices. Fourth, the interplay and synergies between private and public cloud approaches and underlying cloud-based resource pooling have evolved during the pandemic. While cloudification has been accelerated and amplified, hypergiants have expanded their footprints.

Significantly, many of the changes, especially those that have led to modifications in the topology, are here to stay and contribute to the ecosystem’s robustness and resilience. Similarly, a range of virtual substitutes for previously exclusively physical activities will likely be partly or entirely integrated into future life and work after the pandemic. We do not anticipate online versus offline work or social norms to return to pre-COVID-19 patterns. In short, we think increased levels of online interaction, telecommuting, and hybrid solutions that change how online and offline activities are conducted will shift, favouring increased online interaction. However, depending on when the next crisis will hit and what form it will take, the challenges to be met may differ considerably from the ones that had to be overcome in this crisis. On the one hand, industry and employment structures will change over time, and thus also the demands for connectivity and the migratability/transferability of tasks and activities. On the other hand, other crises may differently impact on the physical world and thus require different responses from the virtual world. Several high-level insights are relevant for policy-makers.

First, they must embrace the evolution of the ecosystem and the evolving interplay and ongoing fusion between the real and virtual worlds to develop an understanding of the possible consequences of different crisis scenarios.

Second, safety net broadband objectives inherently represent moving targets. Whereas periodic reassessments of the set of desirable or essential applications and functionality that should be provided by our digital infrastructure for the evolving ‘new normal’ is warranted, it is also important to better understand and have plans for how to respond in potential crisis scenarios. More interdisciplinary research will be needed to embrace these questions and to provide the insights needed to meaningfully address the challenges ahead and to ensure an ecosystem that is not only technologically resilient but also provides the basis for social and economic participation and resilience.

Third, and finally, as the Internet ecosystem continues to become more complex and the boundaries between edge and core, mobile and fixed, transmission and computing and storage services blur, the number of private and public stakeholders with a joint and co-dependent role in ensuring the smooth operation of the digital infrastructure necessarily leaves significant important decision-making to market-based processes (as opposed to centralised control). This is in keeping with the decades long trend towards more light-handed regulation (as opposed to the legacy model of postal, telegraph, and telephone services and public utility regulation of telecommunication networks). The fact that the Internet ecosystem supported on the networks of competing yet interdependent service provider networks was able to meet the challenge posed by the pandemic attests to the robustness of the market process and helps affirm that although we believe that continued regulatory and policy engagement is necessary to promote the digital future we need and desire, the markets are mostly working, at least so far.

Appendix 2.1: Selected Reports and Studies About the Impact of COVID-19 on Internet Traffic