Long-term drivers of broadband traffic in next-generation networks

At present, H2H communications over broadband networks rely mainly on email, online chat (e.g. MSN) and audio/video calls (e.g. Skype). It is expected that these services will be gradually combined into one integrated and highly flexible application for online (real-time) as well as offline (leave-a-message) communications. Moreover, everyone will be assigned a universal unique ID or a personal account. Most H2H messages are likely to be multimedia with embedded video and collections of high-resolution images and sounds. The current video technologies are being evolved towards being capable to fully exploit the potential limits of human sighting such as stereoscopic and 3D viewing and the capability to sense the direction the person is looking at and at which object he/she is focusing attention. Ultimately, the holographic video of the scene may be transmitted. Furthermore, the availability of additional senses will enhance and change the applications for human communications as we know them today. The broadband network users will be able to experience full-extent virtual reality with holographic images and sounds, touch and smell feelings, perhaps even enriched with the taste. Such new rich multimedia communications will be used extensively by social networking and gaming applications, and more importantly, they will incur much higher bandwidth requirements than their current versions.

Majority of contents in 20 years time are going to be generated by the broadband subscribers in their premises. Many applications and services on the broadband networks are becoming gradually highly personalized which will contribute to increased traffic variations. The search engines have evolved to be more intelligent with optimized presentation of the search results. The multimedia will become searchable to the extent that is now only possible for the text-based contents. The applications will be getting a lot smarter and provide a high level of interactivity. Future traffic will be much more affected by attributes such gender, age, emotional state, ethnical background and other such factors. This development is already evident in Japan where multiple sensors are exploited to collect and analyse data for advertising purposes [25]. These developments are further supported by the progress in artificial intelligence and discovery informatics [13] which are playing increasingly important roles in the creation of fully customized contents. Furthermore, it is expected that the broadband networks will be used much more efficiently, for example, by providing the contents in several multi-resolution descriptions chosen for given context and scenario. These developments require accurate predictive models of the users’ behaviour and their intention.

Privacy is one of the top research, ethical and legal issues of the current Internet. The trend is to assign an ID not only to all network hosts but also to all network processes, activities and transactions. Home automation has been established to control lighting, heating, ventilation, air conditioning, security systems, home robots and appliances, and many other home systems including the home networks for distribution of audio and video in the households [37]. There is a strong emerging trend to embed broadband network connections into all home devices to enable their remote control over the Internet. The IoT and M2M communications (where devices and/or software components communicate) [11] are expected to increase the bandwidth demand. However, it is unlikely that the IoT and M2M communications will significantly affect the broadband traffic outward/inward of the households since most of this traffic will remain within the home network boundaries. The M2M communications can be also found in cars where sensors are frequently used to aid the car maintenance, to inform the developers [35] and to control car settings through dedicated applications [15]. In addition, the M2M communications are used for the electricity, gas and water utility metering in building the smart grids [33], and there are many other emerging applications. On the other hand, the video surveillance applications for increased safety and security are becoming very attractive, and, unlike the locally constrained M2M communications (used at home and in-car networks), they are likely to require significant additional bandwidth. Such applications are expected to grow rapidly and will include different kinds of sensors for automated control of machines. One of the distinct features of using sensors is that they will become almost ubiquitous, but more importantly, they will represent permanent traffic sources possibly requiring dedicated broadband connections which can generate large aggregated traffic over time. This will change requirements on the broadband network design in order to accommodate such dedicated links.

There is a noticeable increase of demand for cloud computing applications [20], which is also driven by proliferation of portable devices with limited computing power and storage [12]. Today, cloud computing includes solutions for delivering hardware and software resources as a service or platform over the broadband networks [29]. For instance, the handheld devices may be used as terminals to access extensive centralized computing resources. The future terminals will have enhanced human-computer interfaces; at minimum, they will be equipped with touch screen, high-resolution display, cameras and other sensors. Alternatively, the computing resources can be deployed or distributed at the network edges which may have some salient benefits. Consequently, cloud computing will change the structure of broadband networks. The related standardization efforts and developments in improving the security and trust of cloud computing are contributing to its acceptance. Furthermore, it is already observed that online storage services are generating a large amount of traffic which can be expected to only increase. Large amounts of data from ubiquitous sensors, other measuring campaigns and, particularly, scientific experiments generate truly massive amounts of data to be stored online in large databases. The data storage and access to such databases is likely to generate large traffic volumes. Thus, the bandwidth requirements of cloud computing and remote processing services are expected to far exceed those of other daily used services (e.g. WWW browsing).

Classroom-based lecturing is becoming an obsolete form of educating students. Traditional classroom lectures are now being enhanced or even, in some cases, replaced by online learning methods. There are many case studies clearly demonstrating this trend. We envision that high-quality interactive video streaming links to join students from anywhere around the world into virtual classrooms and virtual labs will be a norm in 20 years time. Online education can be further enhanced by the use of remote controllers including robots. A very similar discussion is applicable to working online supported by emergence of virtual offices and even virtual enterprises. Hence, education and work online will be significant drivers of future broadband traffic.

The broadband networks today are mainly concerned with delivering traffic to residential users. In 20 years, the demand for broadband services will become truly ubiquitous. In addition to the residential (home) and enterprise access, the broadband access will be required in public areas and spaces such as parks, streets, bus stops, shopping malls, restaurants, in cars and buses, etc. Majority of this broadband access will be realized wirelessly; however, it is very likely that backhaul traffic will have to be collected by wired networks in order to be cost-effective and in order to provide the sufficient bandwidth for such extremely large aggregated traffic. We believe that this is the main research direction when considering opportunities for significant investments in future broadband networks, especially in 20 years time. Inevitably, such network developments will be happening in the new market environments and with new business models. The future broadband networks will require different topology and architecture designs as well as different network management strategies in order to provide truly ubiquitous broadband access everywhere. For example, traffic will be automatically re-routed to most efficiently exploit the available instantaneous network transport capacity. In addition, new applications and services can be developed that are more aware of the broadband network state and that can adapt their parameters. In summary, the broadband network infrastructure is a trade-off between the transport capacity and its implementation and operational cost. It is expected that the capacity will remain the main driver in the near future; however, at some point within the next 20 years, the bandwidth demand may saturate, and the cost factors may dominate the broadband network developments [41].

Most of today’s 2D video streaming methods use either standard definition (SD) or high definition (HD) format. The minimum and maximum bandwidth requirements of the SD and HD video streaming with MPEG-2 and MPEG-4 compressions, respectively, are given in Table 1 [23].

The 3D video technology is still under active development and standardization activities. There are different methods for displaying and encoding 3D video. Some of them are already established while others have just been introduced. The ultimate aim of 3D video is to produce static and, later on, also moving holographic pictures. The main factors influencing 3D video development are the implementation and computing complexity, availability of network bandwidth and ultimately adoption by the consumers. Thus, the main players in adoption of 3D video services are the ISP, network infrastructure providers, TV equipment manufacturers, content providers and subscribers. For example, Philips started to develop an auto-stereoscopic TV to have been launched at the end of 2011, but then, this project was cancelled due to slow adoption of 3D video by the customers [27]. On the other hand, Toshiba, Samsung, Sony and Panasonic launched their auto-stereoscopic TV in the past 2 years [34, 36]. Toshiba makes further investments into developing higher resolution 3D TV sets aiming to provide simultaneous 3D views which are more than any other available TV content of today [44].

The 3D video technologies can be classified into two main classes: 3D video with added depth perspective and 3D multi-view video. The first approach is relatively well established by now, and it uses stereoscopic display with viewing glasses or with parallax barriers. The second approach uses auto-stereoscopic display without any need for viewing glasses. We next review the common 3D video encoding formats.

The 3D video encoding standards are launched every 3 years [42]. It takes about one additional year for the 3D video codec to become considered by wider markets, so we assume that a new 3D video format is introduced every 4 years. Although the number of parallel video streaming channels is likely to be increasing in the future with the introduction of new multimedia applications, we assume that at any time each household is most likely consuming one single video stream. The traffic upper and lower bounds are obtained assuming video at high quality (e.g. high-definition TV) and at minimum quality (e.g. small-screen TV), respectively. These bounds are given in Tables 3 and 4 including the calculated YoY traffic growth rates which are the key parameter for dimensioning the broadband networks. The upper bound shows good approximation of the logistic curve of traffic demand which saturates in the last 4 years of the 20-year period considered. The spread between the upper and lower bounds could be reduced by assuming more realistic conditions.

Upstream traffic is expected to grow due to development of new interactive multimedia as well as non-interactive and/or non-multimedia applications; however, the expected growth rate in the upstream will be smaller than that in the downstream. The multimedia applications requiring significant uplink bandwidth are those for interactive communications with embedded video. The cameras capable of recording 3D video are likely to become available within the 20-year horizon. The upload of 3D videos to multimedia or storage servers will contribute significantly to the uplink bandwidth demands even though these uploads could be scheduled for times when the uplink bandwidth becomes available (e.g. overnight or in early morning hours). Furthermore, as discussed above, new M2M communications and other emerging applications and services will make broadband traffic generated at the subscriber’s premises to appear peakier with large instantaneous variations. Consequently, the ratio of the downlink to uplink traffic volumes in today’s broadband connections being 10:1 will be much more balanced in future broadband networks [21]; this ratio may eventually become 1:1 even though it is difficult to predict how soon this will happen.

In order to gain a first insight into traffic variations in the residential households, we assess how likely or how often traffic delivered to the households is going to reach the previously computed upper bounds. We assume the average usage hours for different applications and user groups as shown in Table 5 [31]. We then calculate the probabilities P ₁, P ₂ and P ₃ corresponding to the probability of accessing the broadband network, the probability of using some multimedia service and the probability of using other non-multimedia applications, respectively (see Table 6). In particular, the probability that all family members (in all age groups) use multimedia with embedded 3D video streaming at the same time and independently from each other is only 0.7 %. The probability that a single adult user consumes a single multimedia stream at any time is 29 %. In other words, the largest bandwidth peak due to multiplexing multiple independent video streams will occur with the probability 0.7 % (i.e. approximately 1 out of 100 households at any time or, equivalently, for any household, for 1 h every 100 h). On the other hand, approximately three out of ten households will generate traffic corresponding to a single video stream at any time, or, equivalently, each household will consume, on average, a single video stream for approximately one third of the day (i.e. 7.2 out of 24 h).