WiFi-based Long Distance networks are seen as a promising alternative for bringing broadband connectivity to rural areas. A key factor for the profitability of these networks is using license free bands. This work quantifies the current spectrum occupancy in our testbed, which covers rural and urban areas alike. The data mining is conducted on the same WiFi card and in parallel with an operational network. The presented evaluations reveal tendencies for various aspects: occupancy compared to population density, occupancy fluctuations, (joint)vacant channels, the mean channel vacant duration, different approaches to model/forecast occupancy, and correlations among related interfaces.
Rural areas all over the world often lack affordable broadband Internet connectivity. This is particularly, but not solely, true for developing and emerging countries. Also rural areas in western countries share similar problems of high capital expenditure (CAPEX) and especially operational expenditure (OPEX) due to vast and sparsely populated areas, which often present an uneconomical environment for deploying traditional wireless carrier equipment. To address these issues, we have developed a carrier-grade heterogeneous multi-radio back-haul architecture which may be deployed to extend, complement or even replace traditional operator equipment. Our Wireless Back-Haul (WiBACK) technology extends the back-haul coverage by building on cost-effective and low-power equipment while still allowing for effective Quality of Service (QoS)-provisioning. In this paper we first present a pilot scenario in Hennef-Theishohn, Germany, where the residents of a remote farm are provided with broadband Internet connectivity using a long-distance, multi-hop WiBACK network. We evaluate the QoS-related performance of this network and show that we can meet QoS demands one expects from a carrier-grade network even under heavy load conditions
Wireless Mesh Networks (WMNs) are often seen as an affordable solution to bring Internet connectivity into rural and previously unconnected regions. To date, the main focus has been to provide access to classical services such as the WWW or email which requires the users to use a personal computer or a recent smart phone. In many developing regions, however, the prevailing end user device is a mobile phone. In order to connect mobile phones to IP-based wireless back-haul networks, the network access points must provide a mobile phone air interface, compatible with GSM or UMTS specifications. Avoiding dependence on a costly mobile operator infrastructure, we propose to deploy GSM or 3GPP nano cells in order to terminate the mobile phone protocols immediately at the local network access points. Therefore, voice or data traffic can be carried over wireless back-haul networks using open protocols such as SIP and RTP. In this paper we present a meshed wireless back-haul network architecture whose access points have been equipped with GSM nano-cells. The voice packets generated by mobile phones are carried across the backhaul network in parallel to typical web or video traffic. We evaluate the QoS handling received by the voice calls across our multi-hop wireless testbed and show that our architecture can provide the resource isolation required to offer uninterrupted VoIP services in parallel to regular Internet traffic.
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