Wireless Ad Hoc and Sensor Networks

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Index 503PPacific digital cellular, 13Packets and packet schedulingDiffserv, 5–6Intserv, 4–5optimized energy-delay subnetworkrouting, 419performance metrics, 124quality of service control, 7–9Parameters, simulation, 476–477Park, Lee and, studies, 215, 237Park and Corson studies, 359Park and Sivakumar studies, 234–235, 468Path lossactive links, 187Bambos power control scheme, 182bounded power overshoot, 188–189cellular network applications, 189–200constrained second-order power control,182–183effect, 290–291, 290–291fading channels, 213fundamentals, 180–182mobile users, 192–193, 194–195peer-to-peer networks, 193–200signal-to-interference protection, 187state-space-based controls design, 183–189uplink transmitter power control,189–190, 190–193, 192PCR, see Peak cell rate (PCR)Peak cell rate (PCR)ATM networks, 2–3network modeling, 86Peer-to-peer networksactive link protection, 204–206ad hoc networks, 240, 240admission control, 200–212admission controller algorithm, 206–212admission delay evaluation, 208, 211, 212algorithms, 240, 240–242Bambos scheme, 182cellular network applications, 189–200constrained second-order power control,182–183controller scheme development, 214–230dropped links, 208, 211, 212fading channels, 212–230feedback, 239–240fundamentals, 177–179, 230, 239IEEE standard 802.11, 240, 240mobile users, 192–193, 226, 228–229path loss, 180–200peer-to-peer network, 207–208, 207–210performance evaluation, 225–226, 227power reset, 240–241radio channel uncertainties, 212–214retransmissions, 240–241simulation, 250–253, 251–252state-space-based controls design,183–189transmitter power control, mobile users,192–193, 194–195uplink transmitter power control,189–190, 190–193, 192wireless network applications, 200–212PEGASIS protocol, 383Peng studies, 110, 149, 430Performance evaluation and metricsexamples, 323–332fading channels, 225–226, 227fair scheduling, 323–332feedback delays, 105, 105–106fundamentals, 323, 375–376optimized energy-delay subnetworkrouting, 396–414, 420–423predictive congestion control, 435–436,456–457, 457–458random topology, 326–332, 326–332simulation, 93–94, 124–125star topology, 323, 324–325, 326variable number of nodes, 378–379,380–381, 382varying node mobility, 376, 377–379, 378Perkins and Bhagwat studies, 359Perkins studies, 359Persistency, QoS, 304Physical interface, 418Physical layer specifications, 25–26Pottie and Kaiser studies, 39Power control, see also specific typeBambos scheme, path loss, 182CDMA, wireless networking, 23distributed adaptive, 237–239effective schemes, 21mobile ad hoc networks, 33–35, 34transmitter, mobile users, 192–193,194–195uplink transmitter, path loss, 189–190,190–193, 192Power control, adaptive and probabilisticanalysis, simulation, 477–483, 478–483decentralized adaptive power control,467–473distributed selection, 467distribution adaptation, 474, 475–476
504 Wireless Ad Hoc and Sensor Networksevaluation metrics, 477, 477fundamentals, 461–463, 483–484mathematical relations, 463–465parameters, simulation, 476–477power distribution, 473–475, 474power update, 468–470probabilistic power control, 473–476problem formulation, 463–467reader design, 476selective backoff, 470–472, 471–472simulation, 476–483standards, 467two-reader model, 465–467, 466Power control, MAC protocolACK frame scenario, 247channel utilization, 243, 246contention time, 247, 252CTS frame scenario, 247design of protocol, 245efficiency of protocol, 248fundamentals, 242–243hidden-terminal problems, 243–244,243–245minimizing overhead impact, 247–248NS-2 implementation, 249, 249overhead analysis, 247–248RTS frame scenario, 247single data frame scenario, 247Power control, RFID reader networksanalysis, simulation, 477–483, 478–483decentralized adaptive power control,467–473distributed selection, 467distribution adaptation, 474, 475–476evaluation metrics, 477, 477fundamentals, 461–463, 483–484mathematical relations, 463–465parameters, simulation, 476–477power distribution, 473–475, 474power update, 468–470probabilistic power control, 473–476problem formulation, 463–467reader design, 476selective backoff, 470–472, 471–472simulation, 476–483standards, 467two-reader model, 465–467, 466Power control (distributed)active link protection, 204–206ad hoc networks, 240, 240admission control, 200–212admission controller algorithm, 206–212admission delay evaluation, 208, 211, 212algorithms, 240, 240–242Bambos scheme, 182cellular network applications, 189–200constrained second-order power control,182–183controller scheme development, 214–230dropped links, 208, 211, 212fading channels, 212–230feedback, 239–240fundamentals, 177–179, 230, 239IEEE standard 802.11, 240, 240mobile users, 192–193, 226, 228–229path loss, 180–200peer-to-peer network, 207–208, 207–210performance evaluation, 225–226, 227power reset, 240–241radio channel uncertainties, 212–214retransmissions, 240–241simulation, 250–253, 251–252state-space-based controls design,183–189transmitter power control, mobile users,192–193, 194–195uplink transmitter power control,189–190, 190–193, 192wireless network applications, 200–212Power control (distributed), path lossactive links, 187Bambos power control scheme, 182bounded power overshoot, 188–189cellular network applications, 189–200constrained second-order power control,182–183fading channels, 213fundamentals, 180–182mobile users, 192–193, 194–195peer-to-peer networks, 193–200SIR protection, 187state-space-based controls design,183–189uplink transmitter power control,189–190, 190–193, 192Power control (distributed), wireless ad hocnetworksabrupt changing channels, 293, 293–294algorithms, 240, 240–242backoff mechanism, 267buffer occupancy state equation, 269channels, 235–237, 243, 246, 261–262comparison of protocols, 257–259,258–259contention time, 247cost function, 270–272
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Wireless Ad Hocand SensorNetworksPr
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18. Chaos in Automatic Control, edi
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CRC PressTaylor & Francis Group6000
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Table of Contents1 Background on Ne
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3 Congestion Control in ATM Network
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5.4.2 Distributed Power Controller
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7.3 Adaptive and Distributed Fair S
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9.2.2 Overview.....................
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the number of connections in each l
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y Maheswaran Thiagarajan, and tirel
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2 Wireless Ad Hoc and Sensor Networ
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10 Wireless Ad Hoc and Sensor Netwo
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2BackgroundIn this chapter, we prov
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Background 51u(k)x n (k + 1)x n (k)
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Background 53with x( 0)being the in
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Background 55with tr(.) the matrix
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Background 57nGiven a function ft (
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Background 592.3.2 Lyapunov Stabili
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Background 61as well as Jagannathan
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Background 63The subsequent example
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Background 65Evaluating this along
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Background 67Now, select the feedba
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Background 69is SISL if and only if
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Background 71L 1 (x)L(x, t)L 0 (x)0
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Background 73for some R > 0 such th
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Background 75Evaluating the first d
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Background 77Section 2.4Problem 2.4
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100 Wireless Ad Hoc and Sensor Netw
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4Admission Controller Design for Hi
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Admission Controller Design for Hig
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7Distributed Fair Scheduling in Wir
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Distributed Fair Scheduling in Wire
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8Optimized Energy and Delay-Based R
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Optimized Energy and Delay-Based Ro
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9Predictive Congestion Control for
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Predictive Congestion Control for W
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Page 476 and 477: Predictive Congestion Control for W
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