The Impact of Adjacent Channel Interference in Multi-Radio Systems using IEEE 802.11

Nachtigall, Jens; Zubow, Anatolij; Redlich, Jens-Peter

doi:10.1109/iwcmc.2008.151

Cited by 39 publications

(29 citation statements)

References 12 publications

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“…Based on this assumption measurements were only conducted with Tx values between 10 dBm to 15 dBm. In comparison to other previously published work, such as [9] and [10], the following results show every combination of Tx and DR with T and RSSI, respectively. As explained in detail in Section II-A for every calculated sample meanμ, CI is also be provided.…”

Section: Multi-radio Experimentsmentioning

confidence: 50%

“…Additionally, their assumption has already been disproved by many researchers, such as [7] [9] [10], ACI issues must be taken into account when conducting multi-radio measurements with IEEE 802.11a hardware. One of the most important pieces of work in relation to this issue are the results of Nachtigall et al [9]. They demonstrated that the number of available non-interfering channels depends on both the antenna separation and the Physical Layer (PHY) modulation.…”

Section: B Adjacent Channel Interferencementioning

confidence: 99%

See 1 more Smart Citation

Measurements and Evaluations for an IEEE 802.11a Based Carrier-Grade Multi-radio Wireless Mesh Network Deployment

Robitzsch

Niephaus

Fitzpatrick

et al. 2009

2009 Fifth International Conference on Wireless and Mobile Communications

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Abstract-Although there currently exists a number of Wireless Local Area Network based mesh network deployments most have been deployed to provide best effort broadband Internet access. Consequently, they cannot meet the requirements of network operators in order to utilise these networks to offer carrier grade services. The goal of providing carrier grade services over a wireless mesh infrastructure requires high performance in terms of throughput and reliability. One way of achieving this increase in performance is to utilise multi-radio Mesh Nodes, however, due to the Physical Layer layer limitations of 802.11a this can have significant problems. This paper analyses these issues and investigates what performance can be expected when frequency multiplexing is considered. The results presented in this paper are based on real measurements taken from multi-radio Mesh Nodes and are evaluated using statistical algorithms. The main contribution of this paper is an analysis of the impact of the Adjacent Channel Interference effect in 802.11a based multi-radio Mesh Nodes.

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Section: Multi-radio Experimentsmentioning

confidence: 50%

Section: B Adjacent Channel Interferencementioning

confidence: 99%

Measurements and Evaluations for an IEEE 802.11a Based Carrier-Grade Multi-radio Wireless Mesh Network Deployment

Robitzsch

Niephaus

Fitzpatrick

et al. 2009

2009 Fifth International Conference on Wireless and Mobile Communications

View full text Add to dashboard Cite

show abstract

“…However, for the 40 MHz link, the impact is less than when it overlaps with 20 MHz links. This is probably due to the mechanism CSMA/CA which in this case has less spurious carrier sensing and less frames are corrupted ( [2,3]). …”

Section: Is It Worth Using 40 Mhz Channels?mentioning

confidence: 99%

“…Many works (e.g., [1][2][3][4][5][6][7][8][9]) study different characteristics of WiFi in practice, but still more practical tests and a larger set of experiments are needed. For example, most of the works are focused only on the 2.4 MHz band or only study a reduced set of aspects of the 5GHz band.…”

Section: Introductionmentioning

confidence: 99%

Rumours and good practices in community networks wireless links

Pérez-Francisco

Boronat

Manzoni

et al. 2014

2014 Sixth International Conference on Ubiquitous and Future Networks (ICUFN)

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Abstract. In wireless community networks, backbone point-to-point links concentrate most of the traffic. Thus, these links are crucial for the overall performance of the network. Network managers have to constantly test and maintain these links to optimise their performance, but their decisions are often based upon rumours or a purely theoretical knowledge of the technologies being used. These sources of information can be very biased and can lead to incorrect decisions in such complex systems. In this work we provide the guidelines to help in wireless links optimization by covering the most common mistakes or questions, and by addressing the critical factors one by one using a real scenario. In our experiments we analyse critical characteristics such as the interference among links, the relation between channel bandwidth and throughput, the impact of output power, and the effect of antenna proximity. We are well aware that the efficiency of wireless networks is very variable and dynamic, therefore this work provides useful hints on how to better deploy an efficient wireless community network.

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“…Therefore, separating APs into different channels may decrease cochannel interference. However, in nonoverlapping channels, an 802.11-based multiradio device suffers board crosstalk, radiation leakage, and adjacent channel interference [5], [32], [33]. These problems are hardware dependent [5] and can be alleviated by utilizing hardware and radio frequency (RF) techniques such as shielding, bandpass filters, and antenna separation by distances or orientations [32], [33].…”

Section: A Ieee 80211 and Ieee 80211smentioning

confidence: 99%

Utilizing Multiple Channels With Fewer Radios in Wireless Mesh Networks

Lin

Tsao

et al. 2011

IEEE Trans. Veh. Technol.

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Abstract-Wireless mesh networking (WMN) is regarded as a low-cost technology for rapid wireless network deployment. However, in a single-channel WMN, the overlapped transmission ranges between relaying mesh points could introduce serious interference. Using multiple radios over multiple channels can decrease the interference and improve the capacity of a WMN, but it increases the cost of a mesh point. One possible solution to balance between interference, hence performance, and cost is utilizing fewer radios that switch among multiple channels instead of using per-channel radios. In this paper, we propose a channel-switching method, called the traffic-aware switching scheme (TRASS), for a mesh point with a limited number of radios. TRASS utilizes the existing IEEE 802.11 mechanisms, i.e., hybrid-coordinationfunction-controlled channel access and power saving, to avoid packet loss during channel switching. A TRASS mesh point monitors the occupied channel time to schedule radios that switch among channels. The implemented TRASS demonstrates 75% throughput improvement by (2, 1), i.e., two-channel single-radio, over (1, 1). (3, 2) and (3, 1) achieve 69.8% and 39.7%, respectively, of the throughput of (3, 3) in the simulated TRASS.Index Terms-Channel switching, IEEE 802.11s, multichannel, multiradio, wireless local area networks (WLANs), wireless mesh network (WMN).

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The Impact of Adjacent Channel Interference in Multi-Radio Systems using IEEE 802.11

Cited by 39 publications

References 12 publications

Measurements and Evaluations for an IEEE 802.11a Based Carrier-Grade Multi-radio Wireless Mesh Network Deployment

Measurements and Evaluations for an IEEE 802.11a Based Carrier-Grade Multi-radio Wireless Mesh Network Deployment

Rumours and good practices in community networks wireless links

Utilizing Multiple Channels With Fewer Radios in Wireless Mesh Networks

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