Lehrstuhl für Kommunikationsnetze
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Item Holistic enlightening of blackspots with passive tailorable reflecting surfaces for efficient urban mmWave networks(2023-04-17) Häger, Simon; Heimann, Karsten; Böcker, Stefan; Wietfeld, ChristianMitigating outage regions is of particular interest for emerging millimeter-wave (mmWave) and future sub-terahertz frequency cellular networks. Whereas smart radio environments based on metasurfaces constitute a key concept for 6G research, current networks cannot be served as new control procedures are required. Although small prototypes are already emerging, costs will be higher for the dense deployment of reconfigurable intelligent surfaces (RISs) compared to passive reflectors. It is argued that passive reflectors can be used to effectively, cost-efficiently, and permanently boost connectivity in well-defined service areas. Leveraging the advantages of 3D printing and spray-painted conductive varnish, we introduce the Holistic Enlightening of bLackspots with passIve reflectOr moduleS (HELIOS) approach which is characterized by its scalability and parametrizability to meet the reflection requirements derived from sophisticated network planning. These slim reflectors meet the core criteria of ease of installation and minimal visual impact on the cityscape, which are imperative for market success. Our measurement-based comparison of prototypes against typical metal/aluminum reflectors shows at least equal reflectivity at a higher practicality of the proposed manufacturing process. The conducted simulation study validates the modular reflector pattern design process and finds a trade-off between the reflector efficiency and the minimum protrusion depth, which relates to the number of modules in the designated mounting area. An urban ray-tracing simulation-based case study further underlines the high applicability of the proposed approach, with the growth of the beyond line-of-sight (LOS) connectivity region being nearly twice as large for a site-tailored heterogeneous HELIOS configuration than that for a simple reflector plate.Item Embracing the future Internet of Things(2019-01-16) Cirillo, Flavio; Wu, Fang-Jing; Solmaz, Gürkan; Kovacs, ErnöAll of the objects in the real world are envisioned to be connected and/or represented, through an infrastructure layer, in the virtual world of the Internet, becoming Things with status information. Services are then using the available data from this Internet-of-Things (IoT) for various social and economical benefits which explain its extreme broad usage in very heterogeneous fields. Domain administrations of diverse areas of application developed and deployed their own IoT systems and services following disparate standards and architecture approaches that created a fragmentation of things, infrastructures and services in vertical IoT silos. Coordination and cooperation among IoT systems are the keys to build “smarter” IoT services boosting the benefits magnitude. This article analyses the technical trends of the future IoT world based on the current limitations of the IoT systems and the capability requirements. We propose a hyper-connected IoT framework in which “things” are connected to multiple interdependent services and describe how this framework enables the development of future applications. Moreover, we discuss the major limitations in today’s IoT and highlight the required capabilities in the future. We illustrate this global vision with the help of two concrete instances of the hyper-connected IoT in smart cities and autonomous driving scenarios. Finally, we analyse the trends in the number of connected “things” and point out open issues and future challenges. The proposed hyper-connected IoT framework is meant to scale the benefits of IoT from local to global.Item Secure and efficient routing in highly dynamic WLAN mesh networks(2015) Sbeiti, Mohamad; Wietfeld, Christian Martin; Holz, ThorstenRecent advances in embedded systems, energy storage, and communication interfaces, accompanied by the falling prices of WLAN routers and a considerable increase in the throughput of a WLAN (IEEE 802.11), have facilitated the proliferation of WLAN Mesh Network (WMN) applications. In addition to their current deployments in less dynamic community networks, WMNs have become a key solution in various highly dynamic scenarios. For instance, WMNs are intended to interconnect self-organized, cooperative, and small Unmanned Aerial Vehicles (UAVs) in a wide range of applications, such as emergency response, environmental monitoring, and ad-hoc network provisioning. Nevertheless, WMNs still face major security challenges as they are prone to routing attacks. Consequently, the network can be sabotaged and, in the case of UAV-WMN-supported missions, the attacker might manipulate payload data or even hijack UAVs. Contemporary security standards, such as the IEEE 802.11i and the security mechanisms of the IEEE 802.11s mesh standard, are vulnerable to routing attacks, as experimentally shown in this research. Therefore, a secure routing protocol is indispensable for making feasible the deployment of WMNs in critical scenarios, such as UAV-WMN-assisted applications. As far as the author of this thesis knows, none of the existing research approaches for secure routing in WMNs have gained acceptance in practice due to their high overhead or strong assumptions. In this research, a new approach, which is called Position-Aware, Secure, and Efficient mesh Routing (PASER), is proposed. This new proposal defeats more attacks than the IEEE 802.11s/i security mechanisms and the well-known, secure routing protocol Authenticated Routing for Ad-hoc Networks (ARAN), without making restrictive assumptions. It is shown that PASER achieves —in realistic UAV-WMN scenarios— similar performance results as the well-established, nonsecure routing protocols Hybrid Wireless Mesh Protocol (HWMP) combined with the IEEE 802.11s security mechanisms. Two representative scenarios are considered: (1) on-demand ubiquitous network access and (2) efficient exploration of sizable areas in disaster relief. The performance evaluation results are produced using an experimentally validated simulation model of WMNs, realistic mobility patterns of UAVs, and an experimentally derived channel model for the air-to-air WMN link between UAVs. The findings of this evaluation are justified by the route discovery delay and the message overhead of the considered solutions.Item Entwurf und Leistungsbewertung von Ad-hoc-Kommunikationsnetzen für den Katastrophenschutz(2013-11-04) Wolff, Andreas Herbert; Wietfeld, Christian Martin; Kays, RüdigerA reliable communications network provides the essential basis for future IT-based services for rescue personnel at an incident scene. Nowadays, the communication in civil protection is based on the digital trunked radio TETRA system, or is still based on analog BOS radio system. These systems do not provide sufficient data rate for multimedia applications. Existing infrastructure networks, such as the public mobile telephony network, can be damaged in a major incident situation and therefore are not fully usable for rescue personnel. To use new multimedia services at the incident scene, rescue personnel therefore dependent on their own local communications network. For the rescue personnel a practicable network deployment is essential, whereas the technology should not hinder the rescue process. Moreover, there are demands on the quality of service of the network, and the performance in terms of the data rate, as for example videos should be transferred from helmet cameras. The aim of this thesis is the design and performance evaluation of a robust communications solution for ad hoc networks in disaster management. To enable a user-friendly network deployment, a reliable networking approach is presented which allows a selfconfiguring ad hoc deployment. Working closely with the fire department, rescue processcompliant network deployment strategies are investigated which can be used as a basis for reliable communication. The key enabling technology of the approach is Wi-Fi communication, which operates in 5GHz band. WLAN stations of one network can interfere with each other or can be interfered by other networks on the same channel. In this work, a method for reducing the interference is introduced. The proposed Interference Avoidance Algorithm (IAA) disables redundant router in the network of rescue personnel. It can be shown by simulations that on average in the investigated scenarios a higher packet delivery ratio can be achieved when IAA is active compared to networks without IAA. In order to reduce interference caused by other networks, a prioritization of the communication of the rescue personnel with the introduction of new communication classes is proposed. This concept is based on the modification of the parameters of the medium access function (DCF) of wireless LAN, which is comparable with IEEE 802.11e but is more prioritized, and is called Emergency-DCF. For its performance evaluation, an existing Markov model is modified and extended. Then, the analytical results are validated by simulation. The feasibility of the method can be validated experimentally. The presented solutions of this thesis have been developed within and were contributed to research projects, where partners from the industry and end-users were actively involved. Thus, the network concept developed within this thesis was tested together with the Dortmund fire brigades during the project MobileEmerGIS. Moreover, the process oriented networking was validated during field tests by Gelsenkirchen fire brigade during the BMBF project SPIDER. The networking concept was also used in a modified version for networking the flying robots in the BMBF project Airshield. With several publications in conferences and presentations at workshops, an international resonance has been achieved. Currently, the results of this thesis are being deployed with the German Red Cross in Bavaria.