Download File - Computer Networks & Information Security
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Destination-Sequenced Distance-Vector (DSDV) Node X takes the following steps: X Y Z If S(X) > S(Y), then X ignores the routing information received from Y If S(X) = S(Y), and cost of going through Y is smaller than the route known to X, then X sets Y as the next hop to Z If S(X) < S(Y), then X sets Y as the next hop to Z, and S(X) is updated to equal S(Y) 170
Hybrid Protocols 171
- Page 119 and 120: Link Reversal Algorithm A B F C E G
- Page 121 and 122: Link Reversal Algorithm Attempts t
- Page 123 and 124: Partial Reversal Method A B F C E G
- Page 125 and 126: Partial Reversal Method A B F C E G
- Page 127 and 128: Partial Reversal Method A B F C E G
- Page 129 and 130: Link Reversal Methods: Advantages
- Page 131 and 132: Link Reversal in a Partitioned Netw
- Page 133 and 134: Full Reversal in a Partitioned Netw
- Page 135 and 136: Full Reversal in a Partitioned Netw
- Page 137 and 138: Temporally-Ordered Routing Algorith
- Page 139 and 140: E D Partition Detection in TORA A N
- Page 141 and 142: E D Partition Detection in TORA A N
- Page 143 and 144: E D Partition Detection in TORA A F
- Page 145 and 146: E D Partition Detection in TORA A F
- Page 147 and 148: TORA Design Decision TORA performs
- Page 149 and 150: So far ... All nodes had identical
- Page 151 and 152: Core-Extraction Distributed Ad Hoc
- Page 153 and 154: Link State Propagation in CEDAR Th
- Page 155 and 156: H G B CEDAR: Core Maintenance A C E
- Page 157 and 158: H G B CEDAR Route Discovery A C E S
- Page 159 and 160: Advantages CEDAR Route discovery/ma
- Page 161 and 162: Proactive Protocols Most of the sc
- Page 163 and 164: Optimized Link State Routing (OLSR)
- Page 165 and 166: Optimized Link State Routing (OLSR)
- Page 167 and 168: OLSR OLSR floods information throu
- Page 169: Destination-Sequenced Distance-Vect
- Page 173 and 174: ZRP All nodes within hop distance
- Page 175 and 176: B F ZRP: Example with Zone Radius =
- Page 177 and 178: B F ZRP: Example with d = 2 A S C D
- Page 179 and 180: LANMAR Routing to Nodes Within Scop
- Page 181 and 182: LANMAR Routing to Nodes Outside Sco
- Page 183 and 184: Geodesic Routing Without Anchors [B
- Page 185 and 186: Routing Protocols discussed so far
- Page 187 and 188: Other Routing Protocols Plenty of
- Page 189 and 190: Power-Aware Routing [Singh98Mobicom
- Page 191 and 192: Power-Aware Routing Possible modifi
- Page 193 and 194: Associativity-Based Routing (ABR) [
- Page 195 and 196: Preemptive Routing [Goff01MobiCom]
- Page 197 and 198: Quality-of-Service Several proposa
- Page 199 and 200: Multicasting in Mobile Ad Hoc Netwo
- Page 201 and 202: Multicasting in MANET Need to take
- Page 203 and 204: AODV Group Sequence Number In our
- Page 205 and 206: Joining the Multicast Tree: AODV H
- Page 207 and 208: Joining the Multicast Tree: AODV H
- Page 209 and 210: Sending Data on the Multicast Tree
- Page 211 and 212: Since J is not a leaf node, it must
- Page 213 and 214: Leaving a Multicast Tree: AODV H C
- Page 215 and 216: Handling a Link Failure: AODV Multi
- Page 217 and 218: Merging Partitions: AODV If the ne
- Page 219 and 220: Merging Partitions: AODV Assume th
Destination-Sequenced Distance-Vector<br />
(DSDV)<br />
Node X takes the following steps:<br />
X Y Z<br />
If S(X) > S(Y), then X ignores the routing information<br />
received from Y<br />
If S(X) = S(Y), and cost of going through Y is smaller than<br />
the route known to X, then X sets Y as the next hop to Z<br />
If S(X) < S(Y), then X sets Y as the next hop to Z, and S(X)<br />
is updated to equal S(Y)<br />
170