@ -52,16 +52,16 @@ Meanwhile, several research groups and network enthusiasts have developed and im
<pclass="subheading">WiFi-based Long Distance Networks</p>
<p>
Most low-tech networks are based on WiFi, the same technology that allows mobile access to the internet in most western households. As we have seen in the previous article, sharing these devices could provide free mobile access across densely populated cities (https://www.lowtechmagazine.com/2015/10/the-4g-network-thats-already-there.html). But the technology can be equally useful in sparsely populated areas. Although the WiFi-standard was developed for short-distance data communication (with a typical range of about 30 metres), its reach can be extended through modifications of the Media Access Control (MAC) layer in the networking protocol, and through the use of range extender amplifiers and directional antennas.[^2]</p>
<p>
Although the WiFi-standard was developed for short-distance data communication, its reach can be extended to cover distances of more than 100 kilometres.</p>
<blockquote>
Although the WiFi-standard was developed for short-distance data communication, its reach can be extended to cover distances of more than 100 kilometres.</blockquote>
<p>
The longest unamplified WiFi link is a 384 km wireless point-to-point connection between Pico El Águila and Platillón in Venezuela, established a few years ago.[^3] [^4] However, WiFi-based long distance networks usually consist of a combination of shorter point-to-point links, each between a few kilometres and one hundred kilometers long at most. These are combined to create larger, multihop networks. Point-to-points links, which form the backbone of a long range WiFi network, are combined with omnidirectional antennas that distribute the signal to individual households (or public institutions) of a community.</p>
<p>
Long-distance WiFi links require line of sight to make a connection -- in this sense, the technology resembles the 18th century optical telegraph (https://www.lowtechmagazine.com/2007/12/email-in-the-18.html).[^5] If there's no line of sight between two points, a third relay is required that can see both points, and the signal is sent to the intermediate relay first. Depending on the terrain and particular obstacles, more hubs may be necessary.[^6]</p>
<p>
Point-to-point links typically consist of two directional antennas, one focused on the next node and the other on the previous node in the network. Nodes can have multiple antennas with one antenna per fixed point-to-point link to each neighbour.[^7] This allows mesh routing protocols that can dynamically select which links to choose for routing among the available ones.[^8]</p>
<p>
Long-distance WiFi links require line of sight to make a connection -- in this sense, the technology resembles the 18th century optical telegraph.</p>
<blockquote>
Long-distance WiFi links require line of sight to make a connection -- in this sense, the technology resembles the 18th century optical telegraph.</blockquote>
<p>
Distribution nodes usually consist of a sectoral antenna (a small version of the things you see on mobile phone masts) or a conventional WiFi-router, together with a number of receivers in the community.<sup>6</sup> For short distance WiFi-communication, there is no requirement for line of sight between the transmitter and the receiver.[^9]</p>
<p>
@ -69,14 +69,14 @@ To provide users with access to the worldwide internet, a long range WiFi networ
<pclass="subheading">Advantages of Long Range WiFi</p>
<p>
Long range WiFi offers high bandwidth (up to 54 Mbps) combined with very low capital costs. Because the WiFi standard enjoys widespread acceptance and has huge production volumes, off-the-shelf antennas and wireless cards can be bought for very little money.[^11] Alternatively, components can be put together from discarded materials (http://roelof.info/projects/%282014%29Pretty_Fly_For_A_Wifi/) such as old routers, satellite dish antennas and laptops. Protocols like WiLDNet run on a 266 Mhz processor with only 128 MB memory, so an old computer will do the trick.<sup>7</sup></p>
Long range WiFi offers high bandwidth (up to 54 Mbps) combined with very low capital costs. Because the WiFi standard enjoys widespread acceptance and has huge production volumes, off-the-shelf antennas and wireless cards can be bought for very little money.[^11] Alternatively, components can be put together from (http://roelof.info/projects/%282014%29Pretty_Fly_For_A_Wifi/) discarded materials such as old routers, satellite dish antennas and laptops. Protocols like WiLDNet run on a 266 Mhz processor with only 128 MB memory, so an old computer will do the trick.<sup>7</sup></p>
<p>
The WiFi-nodes are lightweight and don't need expensive towers -- further decreasing capital costs, and minimizing the impact of the structures to be built.<sup>7</sup> More recently, single units that combine antenna, wireless card and processor have become available. These are very convenient for installation. To build a relay, one simply connects such units together with ethernet cables that carry both signal and power.<sup>6</sup> The units can be mounted in towers or slim masts, given that they offer little windload.<sup>3</sup> Examples of suppliers of long range WiFi components are Ubiquity (https://www.ubnt.com/), Alvarion (http://www.alvarion.com/) and MikroTik (http://www.mikrotik.com/), and simpleWiFi (https://www.simplewifi.com/).</p>
<p>
Long Range WiFi makes use of unlicensed spectrum and offers high bandwidth, low capital costs, easy installation, and low power requirements.</p>
The WiFi-nodes are lightweight and don't need expensive towers -- further decreasing capital costs, and minimizing the impact of the structures to be built.<sup>7</sup> More recently, single units that combine antenna, wireless card and processor have become available. These are very convenient for installation. To build a relay, one simply connects such units together with ethernet cables that carry both signal and power.<sup>6</sup> The units can be mounted in towers or slim masts, given that they offer little windload.<sup>3</sup> Examples of suppliers of long range WiFi components are (https://www.ubnt.com/) Ubiquity, (http://www.alvarion.com/) Alvarion and (http://www.mikrotik.com/) MikroTik, and (https://www.simplewifi.com/) simpleWiFi.</p>
<blockquote>
Long Range WiFi makes use of unlicensed spectrum and offers high bandwidth, low capital costs, easy installation, and low power requirements.</blockquote>
<p>
Long range WiFi also has low operational costs due to low power requirements. A typical mast installation consisting of two long distance links and one or two wireless cards for local distribution consumes around 30 watts.<sup>16</sup> [^12] In several low-tech networks, nodes are entirely powered by solar panels and batteries. Another important advantage of long range WiFi is that it makes use of unlicensed spectrum (2.4 and 5 GHz), and thus avoids negotiations with telecom operators and government. This adds to the cost advantage and allows basically anyone to start a WiFi-based long distance network.<sup>9</sup></p>
<p>Long Range WiFi Networks in Poor Countries</p>
<pclass="subheading">Long Range WiFi Networks in Poor Countries</p>
<p>The first long range WiFi networks were set up ten to fifteen years ago. In poor countries, two main types have been built. The first is aimed at providing internet access to people in remote villages. An example is the Akshaya network in India, which covers the entire Kerala State and is one of the largest wireless networks in the world. The infrastructure is built around approximately 2,500 "computer access centers", which are open to the local population -- direct ownership of computers is minimal in the region.[^13]
Another example, also in India, are the AirJaldi networks which provide internet access to approximately 20,000 users in six states, all in remote regions and on difficult terrain. Most nodes in this network are solar-powered and the distance between them can range up to 50 km or more.[^14] In some African countries, local WiFi-networks distribute internet access from a satellite gateway.[^15] [^16]</p>
@ -92,7 +92,7 @@ Consequently, with each new user, the network becomes larger. There is no a-prio
<pclass="subheading">Wireless links in the Spanish Guifi network.</p>
<p>
Despite the lack of reliable statistics, community networks seem to be rather succesful, and there are several large ones in Europe, such as Guifi.net (Spain), Athens Wireless Metropolitan Network (http://www.awmn.gr/content.php?s=ce506a41ab245641d6934638c6f6f107) (Greece), FunkFeuer (https://www.funkfeuer.at/) (Austria), and Freifunk (https://freifunk.net/en/) (Germany). <sup>8</sup><sup>22</sup> [^23] [^24] The Spanish network is the largest WiFi-based long distance network in the world with more than 50,000 kilometres of links, although a small part is based on optic fibre links. Most of it is located in the Catalan Pyrenees, one of the least populated areas in Spain. The network was initiated in 2004 and now has close to 30,000 nodes, up from 17,000 in 2012.<sup>8</sup><sup>22</sup></p>
Despite the lack of reliable statistics, community networks seem to be rather succesful, and there are several large ones in Europe, such as Guifi.net (Spain), Athens Wireless Metropolitan Network(Greece) (http://www.awmn.gr/content.php?s=ce506a41ab245641d6934638c6f6f107), FunkFeuer (Austria) (https://www.funkfeuer.at/), and Freifunk (Germany) (https://freifunk.net/en/). <sup>8</sup><sup>22</sup> [^23] [^24] The Spanish network is the largest WiFi-based long distance network in the world with more than 50,000 kilometres of links, although a small part is based on optic fibre links. Most of it is located in the Catalan Pyrenees, one of the least populated areas in Spain. The network was initiated in 2004 and now has close to 30,000 nodes, up from 17,000 in 2012.<sup>8</sup><sup>22</sup></p>
<p>
Guifi.net provides internet access to individuals, companies, administrations and universities. In principle, the network is installed, powered and maintained by its users, although volunteer teams and even commercial installers are present to help. Some nodes and backbone upgrades have been succesfully crowdfunded by indirect beneficiaries of the network.<sup>8</sup><sup>22</sup></p>
<pclass="subheading">
@ -106,16 +106,16 @@ However, the low-tech networks that distribute internet access to a large user b
Therefore, the worst-case average bandwidth available per machine is approximately 1.9 kbps, which is slow even in comparison to a dial-up connection (56 kbps). And this can be considered a really good connectivity compared to typical rural settings in poor countries.[^26] To make matters worse, such networks often have to deal with an intermittent power supply.</p>
<p>
Under these circumstances, even the most common internet applications have poor performance, or don't work at all. The communication model of the internet is based on a set of network assumptions, called the TCP/IP protocol suite. These include the existence of a bi-directional end-to-end path between the source (for example a website's server) and the destination (the user's computer), short round-trip delays, and low error rates.</p>
Many low-tech networks in poor countries do not conform to these assumptions. They are characterized by intermittent connectivity or "network partitioning" -- the absence of an end-to-end path between source and destination -- long and variable delays, and high error rates.<sup>21</sup> [^27] [^28]</p>
<pclass="subheading">Delay-Tolerant Networks</p>
<p>
Nevertheless, even in such conditions, the internet could work perfectly fine. The technical issues can be solved by moving away from the always-on model of traditional networks, and instead design networks based upon asynchronous communication and intermittent connectivity. These so-called "delay-tolerant networks" (DTNs) have their own specialized protocols overlayed on top of the lower protocols and do not utilize TCP. They overcome the problems of intermittent connectivity and long delays by using store-and-forward message switching.</p>
<p>
Information is forwarded from a storage place on one node to a storage place on another node, along a path that eventually reaches its destination. In contrast to traditional internet routers, which only store incoming packets for a few milliseconds on memory chips, the nodes of a delay-tolerant network have persistent storage (such as hard disks) that can hold information indefinitely.<sup>27</sup><sup>28</sup></p>
<p>
Delay-tolerant networks combine well with renewable energy: solar panels or wind turbines could power network nodes only when the sun shines or the wind blows, eliminating the need for energy storage.</p>
Information is forwarded from a storage place on one node to a storage place on another node, along a path that *eventually* reaches its destination. In contrast to traditional internet routers, which only store incoming packets for a few milliseconds on memory chips, the nodes of a delay-tolerant network have persistent storage (such as hard disks) that can hold information indefinitely.<sup>27</sup><sup>28</sup></p>
<blockquote>
Delay-tolerant networks combine well with renewable energy: solar panels or wind turbines could power network nodes only when the sun shines or the wind blows, eliminating the need for energy storage.</blockquote>
<p>
Delay-tolerant networks don't require an end-to-end path between source and destination. Data is simply transferred from node to node. If the next node is unavailable because of long delays or a power outage, the data is stored on the hard disk until the node becomes available again. While it might take a long time for data to travel from source to destination, a delay-tolerant network ensures that it will eventually arrive.
Delay-tolerant networks further decrease capital costs and energy use, leading to the most efficient use of scarce resources. They keep working with an intermittent energy supply and they combine well with renewable energy sources: solar panels or wind turbines could power network nodes only when the sun shines or the wind blows, eliminating the need for energy storage.</p>
@ -124,7 +124,7 @@ Delay-tolerant networks further decrease capital costs and energy use, leading t
Delay-tolerant networking can take surprising forms, especially when they take advantage of some non-traditional means of communication, such as "data mules".<sup>11</sup> [^29] In such networks, conventional transportation technologies -- buses, cars, motorcycles, trains, boats, airplanes -- are used to ferry messages from one location to another in a store-and-forward manner.</p>
<p>
Examples are DakNet and KioskNet, which use buses as data mules.[^30] [^31] [^32] [^33] [^34] In many developing regions, rural bus routes regularly visit villages and towns that have no network connectivity. By equipping each vehicle with a computer, a storage device and a mobile WiFi-node on the one hand, and by installing a stationary WiFi-node in each village on the other hand, the local transport infrastructure can substitute for a wireless internet link.<sup>11</sup></p>
Outgoing data (such as sent emails or requests for webpages) is stored on local computers in the village until the bus comes withing range. At this point, the fixed WiFi-node of the local computer automatically transmits the data to the mobile WiFi-node of the bus. Later, when the bus arrives at a hub that is connected to the internet, the outgoing data is transmitted from the mobile WiFi-node to the gateway node, and then to the internet. Data sent to the village takes the opposite route. The bus -- or data -- driver doesn't require any special skills and is completely oblivious to the data transfers taking place. He or she does not need to do anything other than come in range of the nodes.<sup>30</sup><sup>31</sup></p>
<p>
@ -140,16 +140,16 @@ Obviously, a delay-tolerant network (DTN) -- whatever its form -- also requires
Browsing and searching the web requires more adaptations. For example, most search engines optimize for speed, assuming that a user can quickly look through the returned links and immediately run a second modified search if the first result is inadequate. However, in intermittent networks, multiple rounds of interactive search would be impractical.<sup>26</sup><sup>32</sup> Asynchronous search engines optimize for bandwith rather than response time.<sup>26</sup><sup>30</sup><sup>31</sup> [^35] [^36] For example, RuralCafe desynchronizes the search process by performing many search tasks in an offline manner, refining the search request based on a database of similar searches. The actual retrieval of information using the network is only done when absolutely necessary.</p>
<p>
Many internet applications could be adapted to intermittent networks, such as webbrowsing, email, electronic form filling, interaction with e-commerce sites, blogsoftware, large file downloads, or social media.
Some DTN-enabled browsers download not only the explicitly requested webpages but also the pages that are linked to by the requested pages.<sup>30</sup> Others are optimized to return low-bandwidth results, which are achieved by filtering, analysis, and compression on the server site. A similar effect can be achieved through the use of a service like Loband (http://www.loband.org/loband/), which strips webpages of images, video, advertisements, social media buttons, and so on, merely presenting the textual content.<sup>26</sup></p>
Some DTN-enabled browsers download not only the explicitly requested webpages but also the pages that are linked to by the requested pages.<sup>30</sup> Others are optimized to return low-bandwidth results, which are achieved by filtering, analysis, and compression on the server site. A similar effect can be achieved through the use of a service like (http://www.loband.org/loband/) Loband, which strips webpages of images, video, advertisements, social media buttons, and so on, merely presenting the textual content.<sup>26</sup></p>
<p>
Browsing and searching on intermittent networks can also be improved by local caching (storing already downloaded pages) and prefetching (downloading pages that might be retrieved in the future).<sup>26</sup> Many other internet applications could also be adapted to intermittent networks, such as electronic form filling, interaction with e-commerce sites, blogsoftware, large file downloads, social media, and so on.<sup>11</sup><sup>30</sup> All these applications would remain possible, though at lower speeds.</p>
<pclass="subheading">
Sneakernets </p>
<p>Obviously, real-time applications such as internet telephony, media streaming, chatting or videoconferencing are impossible to adapt to intermittent networks, which provide only asynchronous communication. These applications are also difficult to run on synchronous networks that have limited bandwidth. Because these are the applications that are in large part responsible for the growing energy use of the internet, one could argue that their incompatibility with low-tech networks is actually a good thing (see the previous article https://www.lowtechmagazine.com/2015/10/can-the-internet-run-on-renewable-energy.html).</p>
<p>Obviously, real-time applications such as internet telephony, media streaming, chatting or videoconferencing are impossible to adapt to intermittent networks, which provide only asynchronous communication. These applications are also difficult to run on synchronous networks that have limited bandwidth. Because these are the applications that are in large part responsible for the growing energy use of the internet, one could argue that their incompatibility with low-tech networks is actually a good thing (see the previous article (https://www.lowtechmagazine.com/2015/10/can-the-internet-run-on-renewable-energy.html).</p>
<p>
Furthermore, many of these applications could be organized in different ways. While real-time voice or video conversations won't work, it's perfectly possible to send and receive voice or video messages. And while streaming media can't happen, downloading music albums and video remains possible. Moreover, these files could be "transmitted" by the most low-tech internet technology available: a sneakernet. In a sneakernet, digital data is "wirelessly" transmitted using a storage medium such as a hard disk, a USB-key, a flash card, or a CD or DVD. Before the arrival of the internet, all computer files were exchanged via a sneakernet, using tape or floppy disks as a storage medium.</p>
<imgid="kris_9"src="content/images/images_kris/9.jpeg"></img><figcaption>Stuffing a cargo train full of digital storage media would beat any digital network in terms of speed, cost and energy efficiency. Picture: Wikipedia Commons.</figcaption>
Just like a data mules network, a sneakernet involves a vehicle, a messenger on foot, or an animal (such as a carrier pigeon https://www.lowtechmagazine.com/2009/02/sneakernet-beats-internet.html). However, in a sneakernet there is no automatic data transfer between the mobile node (for instance, a vehicle) and the stationary nodes (sender and recipient). Instead, the data first have to be transferred from the sender's computer to a portable storage medium. Then, upon arrival, the data have to be transferred from the portable storage medium to the receiver's computer.<sup>30</sup> A sneakernet thus requires manual intervention and this makes it less convenient for many internet applications.</p>
<imgid="kris_9"src="content/images/kris-de-decker_how-to-build-a-low-tech-internet-9.jpeg"></img><figcaption>Stuffing a cargo train full of digital storage media would beat any digital network in terms of speed, cost and energy efficiency. Picture: Wikipedia Commons.</figcaption>
Just like a data mules network, a sneakernet involves a vehicle, a messenger on foot, or an animal (such as a carrier pigeon (https://www.lowtechmagazine.com/2009/02/sneakernet-beats-internet.html). However, in a sneakernet there is no automatic data transfer between the mobile node (for instance, a vehicle) and the stationary nodes (sender and recipient). Instead, the data first have to be transferred from the sender's computer to a portable storage medium. Then, upon arrival, the data have to be transferred from the portable storage medium to the receiver's computer.<sup>30</sup> A sneakernet thus requires manual intervention and this makes it less convenient for many internet applications.</p>
<p>
There are exceptions, though. For example, a movie doesn't have to be transferred to the hard disk of your computer in order to watch it. You play it straight from a portable hard disk or slide a disc into the DVD-player. Moreover, a sneakernet also offers an important advantage: of all low-tech networks, it has the most bandwidth available. This makes it perfectly suited for the distribution of large files such as movies or computer games. In fact, when very large files are involved, a sneakernet even beats the fastest fibre internet connection. At lower internet speeds, sneakernets can be advantageous for much smaller files.
Technological progress will not lower the advantage of a sneakernet. Digital storage media evolve at least as fast as internet connections and they both improve communication in an equal way.</p>
@ -162,15 +162,12 @@ Depending on their level of resilience, low-tech networks can remain in operatio
<p>
Such a hybrid system of online and offline applications would remain a very powerful communication network -- unlike anything we had even in the late twentieth century. Even if we envision a doom scenario in which the wider internet infrastructure would disintegrate, isolated low-tech networks would still be very useful local and regional communication technologies. Furthermore, they could obtain content from other remote networks through the exchange of portable storage media. The internet, it appears, can be as low-tech or high-tech as we can afford it to be.</p>
</div>
<divclass="bio_3">
<p>Published on the LOW-TECH MAGAZINE https://www.lowtechmagazine.com/2015/10/how-to-build-a-low-tech-internet.html on October 26, 2015, (edited by Jenna Collett https://www.linkedin.com/pub/jenna-collett/1a/925/b3)
<pclass="extra_info">Published on the LOW-TECH MAGAZINE (https://www.lowtechmagazine.com/2015/10/how-to-build-a-low-tech-internet.html) on October 26, 2015, (edited by Jenna Collett https://www.linkedin.com/pub/jenna-collett/1a/925/b3)
</p>
</div>
<divclass="bio_3">
DIY: Wireless networking in the developing world (Third Edition) is a free book about designing, implementing and maintaining low-cost wireless networks. Available in English, French, and Spanish. http://wndw.net/book.html#readBook</div>
<pclass="extra_info">
DIY: Wireless networking in the developing world (Third Edition) is a free book about designing, implementing and maintaining low-cost wireless networks. Available in English, French, and Spanish. (http://wndw.net/book.html#readBook)</p>