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The [http://www.pdos.lcs.mit.edu/roofnet/ MIT Roof Net project] has demonstrated that it is possible to provide an 802.11b-based wireless network backbone infrastructure in a city like Boston (MA). The Berlin Roof Net project tries to determine if a similar network can be setup in Berlin/Germany.
Wireless multi-hop mesh networks play an increasingly important role as backbones for sensor networks and as community networks that provide Internet access in urban areas. The [http://www.pdos.lcs.mit.edu/roofnet/ MIT Roof Net project] has demonstrated that it is possible to supply a large city, such as Boston, with IP network access over an 802.11-based wireless mesh network. The Berlin Roof Net project investigates if a similar (even larger) network can be setup in the city of Berlin and whether such a network can be build in a completely self-organizing/self-configuring way. The Berlin Roof Net project is run by volunteer students of the Computer Science Department at Humboldt University Berlin. Mesh nodes are run independently by the students with their own equipment.


<span style="color:#FF0000"><b>News:</b> Berlin RoofNet goes Open Source.</span>
The Boston network consists of approximately 40 nodes that are mounted on the roofs of buildings (hence the name ’roof net’) and is operated by students and other volunteers. RoofNet nodes discover each other automatically and create a mesh network, which, with the help of proper routing protocols, allow for transmission of IP packets between any two nodes of the network, with data rates of about 1Mbps.
All sources are accessible via [http://sartrac.informatik.hu-berlin.de/brn SarTrac].


[[Image:-Mesh.png|thumb|Mesh Network]]
Berlin has unique properties that make the establishment of such a roof network challenging:
===Vision===
A community network must be usable for inexperienced end users; thus self-organization is essential. On the one hand, we are working on protocols for ad-hoc wireless multi hop mesh networks, where the client is fully freed from such mundane tasks as IP configuration, etc. On the other hand, the community mesh network itself shall be fully self-organized thus no operator or provider is required.


Realizing a wireless mesh network turns out to be non-trivial. One of their biggest challenges is the insufficient scalability with increasing number of nodes and users. The most important reason for this phenomenon can be found in the structure of a multi-hop network: a node is responsible not only for the transmission of its own data, but also for forwarding packets of other nodes. No less significant is the fact that wireless network nodes in close proximity interfere with each other because they share the same medium. With the help of our Berlin RoofNet testbed we can develop, test and evaluate new routing protocols for wireless multi-hop mesh networks.
* Berlin has generally higher buildings with more metal structures than Boston.
* Distances between project participants tend to be larger in Berlin than in Boston.
* It is yet unknown whether the mounting of RoofNet nodes/antennas on buildings is practicable in Berlin.
* Radio interference may be more intense in Berlin due to more systems that are simultaneously operated at 2.4 GHz.
* The acceptance of radio-based communication by the general public may be less pronounced in Berlin than in Boston.


[[Image:Brnviewer.png|thumb|BRN Realtime Map]]
===Overview===


[[Project Status|Project Status]]
==Real-time Map==
* '''Real-time''' status of the indoor testbed [http://sarwiki.informatik.hu-berlin.de/~tolja/cgi-bin/brnlinkmetric.svg] (Adobe SVG plugin [http://www.adobe.com/svg/viewer/install/main.html] required)
[[Image:Brnviewer.png|none|BRN Viewer]]


[[BRN-Development|Software]]
* '''The old list of mesh nodes has been moved to clear some space.''' See [[BrnMeshNodes| list of mesh nodes]].
See [[DhtMeshNodes| list of dht mesh nodes]].


[[BRN-Hardware|Hardware]]
==MSC Tracer for BRN==
* MSC Tracer provides on-line behaviour of a Click router embedded NS2 simulator. [[Image:Brntracer.png|thumb|250px|Description]]


[[Brn.Sim|Brn.Sim Simulation Tools]]
==Project Status==


[[Real-time Map|Realtime Map]]
[[Image:Roadmap.png|thumbnail|center|500px|BRN-RoadMap]]


[[BRN Thesis Proposals|Thesis Proposals]]
==Frequently Asked Questions about the Berlin RoofNet Project==


[[BRN Further Info|Further Information]]
'''Q: What is Berlin Roof Net?'''


[[BRN Other|Other]]
'''A:''' 'Berlin Roof Net' is a project run by volunteer students of the [http://www.informatik.hu-berlin.de/ Computer Science Department] at [http://www.hu-berlin.de/ Humboldt University Berlin]. The goal is to construct a network of nodes (access points) which share Internet access over wireless radio connections. The access points are run independently by the students with their own equipment.


[[BRN FAQ|FAQ]]
The project was inspired by the [http://www.pdos.lcs.mit.edu/roofnet/ MIT RoofNet] project in Boston, USA.


[[Licensing Policy]]


[[Image:BrnLogo2.png|thumb|Berlin RoofNet]]
'''Q: Which wireless communication technologies are used?'''


===Contact===
'''A:''' One technology that is economically feasible for our purpose is IEEE 802.11b, also known as [[WiFi]] or [[Wireless LAN]]. However, the communication range of this technology is rather limited, especially in cities with no line of sight (NLOS) between the participating nodes. We would like to augment our system with 802.16a (WiMax) technology, which provides longer communication ranges and higher data rates, as soon as such equipment becomes available at a reasonable price.


Further information about BerlinRoofNet Project can be found here [http://www.berlinroofnet.de/ BRN Testbed].
'''Q: Is it safe for my health?'''
If you have any questions please write us an e-mail to zubow@informatik.hu-berlin.de.

'''A:''' [[WaveLAN]] operates at 0.25 watts in a bursty mode (i.e. only when data is actually transmitted). Cellular phones go up to 3 watts and microwave ovens leak even more - and they are generally considered 'safe enough'.

All devices on the US market are approved by the FCC, which has a good public document on [http://www.fcc.gov/oet/rfsafety/ RF Safety].

'''Q: What is the vision?'''

'''A:''' This is a research project. Researchers often take a simple good idea and push it to its logical extreme. From this they learn a lot and finally understand what's possible and what is not. Then, taking one step back from the extreme approach, real good practical systems can be built. Here is our extreme story:

Traditional communication networks are owned by operators; i.e. companies who invest money into the deployment of cables and devices, and who operate and maintain those resources in order to offer services to users. To recover their investments (and to make some profit) they charge their customers.

This may change: Falling hardware prices combined with ever increasing functionality may make it feasible to outsource the function of an operator (company) to the service users. The software that normally runs on operator-owned computers may be split into components that are executed at end-user owned equipment (such as computers, access points or mobile phones). Cables may be replaced by wireless links - which are even free if operated in an unlicensed frequency spectrum, such as 2.4GHz or 5GHz .

Easy? Not so fast! There is still a lot of plumbing and configuration necessary to build and run a reliable network - just that it has to happen automatically now. And, in the event that something goes wrong, the system has to be able to automatically recover from ANY failure by itself - there is no operator to help. ... and this is exactly where our research comes into play. We want to see how far the idea of 'outsourcing the network operator to the end-user' can go with today's technology. If we are successful, those community owned networks may become a vital component in making Internet communication accessible to more people, for little or no money.

Is this the death of telephone operator companies? By no way! Certain people and businesses will always require high quality communication services - and they are willing to pay for that extra quality. Those services will continue to be provided by commercial operators - at least for now :-)

==Thesis Proposals==

See [http://sar.informatik.hu-berlin.de/research/thesis_proposals.htm] for a list of currently available thesis proposals that are related to the Berlin Roof Net project.

See [[BRN Sub Projects]] for current (ongoing) thesis work/projects.


==Further Information==

Technical Papers:

* [[Programming the Linksys WRT54GS Wireless Broadband Router]] (Tutorial)
* [[:Image:WiMax-LOS.pdf|WiMax's technology for LOS and NLOS environments]] (pdf)
* [[Using StandardizedDevelopmentEnvironment|Using Standardized Development Environment for OpenWRT]] (Tutorial)
* [[Upgrading the Linksys WRT54GS antenna]]
* [[Hacking the Netgear wgt634u]]
* [[OpenWGT]] http://openwgt.informatik.hu-berlin.de/

Known Hardware:

* [[BRN:Hardware:WPNT843 Netgear WPNT834 (uses MIMO)]]
* [http://www.meshnode.org Meshnode]

General Press:

* [http://news.zdnet.co.uk/communications/wireless/0,39020348,39189953,00.htm Intel has unveiled proposal for 802.11s, a new mesh wireless networking standard]. ZDNet UK, Mach 2005 ([[:Image:802_11s.pdf|cached pdf]])
* [http://www.spiegel.de/netzwelt/technologie/0,1518,344668,00.html Utopien aus Sauerkrautdosen]. Spiegel (German), March 2005. ([[:Image:UtopienAusSauerkrautdosen.pdf|cached pdf]])
* [http://www.spiegel.de/netzwelt/netzkultur/0,1518,344502,00.html Breitband zwischen Deich und Düne]. Spiegel (German), March 2005. ([[:Image:BreitbandZwischenDeichUndDüne.pdf|cached pdf]])
* [http://www.ndrtv.de/ratgebertechnik/themen/20060218_dsl_alternativen.html DSL-Alternativen – Schnelles Internet per Satellit und Funk]. NDR (German), February 2006. ([[:Image:DSL-Alternativen.pdf|cached pdf]])


Similar projects in other cities:

* [http://www.pdos.lcs.mit.edu/roofnet/ MIT RoofNet in Boston]
* [http://www.nycwireless.net/ New York Wireless]
* [http://www.austinwireless.net/ Austin Wireless]
* [http://www.seattlewireless.net/ Seattle Wireless]
* http://wavelan-berlin.de -- Freies Netz in Berlin
* http://freifunk.net -- Freie (Wlan)Netze in Dtl., Österreich und der Schweiz
* http://www.funkfeuer.at/ -- Freies Netz in Wien
* [http://www.wlanhain.de/technik1.html WlanHain (Wireless LAN in Berlin Friedrichshain)]
* [http://www.wlanhsh.de/ WlanHSH (Wireless LAN in Berlin Hohenschönhausen / Weißensee)]
* [http://degnet-wdsl.de/ wireless DSL in Niederbayern]


Related Projects:
* [[ClickModularRouter|Click Modular Router]]

Working Groups
* [http://research.microsoft.com/mesh/ Microsoft Mesh]

Other:
* [[BrnHistory|Berlin Roof Net History]]
* [http://www.intel.com/research/exploratory/motes.htm Intel Mote (Self-Organizing Sensor Networks)]
* [http://www.linux-magazin.de/Service/Books/Buecher/HW-Treiber/x19513.html Die Struktur net_device im Detail]

==Development==

* BRN-Doxygen [http://nfs-student/doxygen/click/]
* BugZilla [http://wiki/cgi-bin/bugzilla/index.cgi]
* Click-Tutorials [http://www.pats.ua.ac.be/index.php?id=software]

Latest revision as of 08:08, 18 November 2010

Wireless multi-hop mesh networks play an increasingly important role as backbones for sensor networks and as community networks that provide Internet access in urban areas. The MIT Roof Net project has demonstrated that it is possible to supply a large city, such as Boston, with IP network access over an 802.11-based wireless mesh network. The Berlin Roof Net project investigates if a similar (even larger) network can be setup in the city of Berlin and whether such a network can be build in a completely self-organizing/self-configuring way. The Berlin Roof Net project is run by volunteer students of the Computer Science Department at Humboldt University Berlin. Mesh nodes are run independently by the students with their own equipment.

News: Berlin RoofNet goes Open Source. All sources are accessible via SarTrac.

Mesh Network

Vision

A community network must be usable for inexperienced end users; thus self-organization is essential. On the one hand, we are working on protocols for ad-hoc wireless multi hop mesh networks, where the client is fully freed from such mundane tasks as IP configuration, etc. On the other hand, the community mesh network itself shall be fully self-organized thus no operator or provider is required.

Realizing a wireless mesh network turns out to be non-trivial. One of their biggest challenges is the insufficient scalability with increasing number of nodes and users. The most important reason for this phenomenon can be found in the structure of a multi-hop network: a node is responsible not only for the transmission of its own data, but also for forwarding packets of other nodes. No less significant is the fact that wireless network nodes in close proximity interfere with each other because they share the same medium. With the help of our Berlin RoofNet testbed we can develop, test and evaluate new routing protocols for wireless multi-hop mesh networks.

BRN Realtime Map

Overview

Project Status

Software

Hardware

Brn.Sim Simulation Tools

Realtime Map

Thesis Proposals

Further Information

Other

FAQ

Licensing Policy

Berlin RoofNet

Contact

Further information about BerlinRoofNet Project can be found here BRN Testbed. If you have any questions please write us an e-mail to zubow@informatik.hu-berlin.de.