List of Tables
1.1 | Differences between cellular and next generation wireless networks |
2.1 | Values of the distance–power gradient in different propagation environments |
2.2 | Current draw of typical WiFi and ZigBee products |
3.1 | Classification of representative mobility models according to different criteria |
5.1 | Values of vRWP for different widths of the speed interval (in m/s) |
8.1 | Main features of the various IEEE 802.11 protocols |
8.2 | List of the most significant amendments to the IEEE 802.11 standard |
9.1 | Main features of some real-world WLAN traces |
10.1 | Monthly correlation in WLAN user mobility reporting, for each pair of monthly sub-traces, the cosine distance of the corresponding steady-state user/AP distribution |
10.2 | Prediction accuracy of the 1-location (1) and 2-locations (2) estimators for different values of the time parameters. Values of Tp,h, and K are expressed in seconds |
10.3 | Probability distributions used in the KKK mobility model. The pause time and speed distributions are derived using min = 0.1 m/s |
11.1 | Main features of the IEEE 802.11a and 802.11p PHY layer specifications |
11.2 | Requirements of ICW and EEBL applications |
17.1 | Short-range wireless technologies for opportunistic network communications |
18.1 | Some representative routing protocols for opportunistic networks |
19.1 | Centrality metrics of the social network displayed in Figure 19.1 |
19.2 | Main features of the data traces analyzed in Karagiannis et al. (2007) |
20.1 | Transition matrix of the Markov chain used to model existence/non-existence of a pairwise wireless link in the Home-MEG model |
20.2 | Optimal parameters of the Home-MEG model for the three data traces shown in Figure 20.11 |
21.1 | The critical transmission range for connectivity with uniform node spatial distribution and distribution generated by RWP mobility for networks of increasing number n of nodes |
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