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We hope that it is more important to know where you are going than to get there quickly. SNU INC Lab. A Survey of Energy Efficient Network Protocols for Wireless Networks Hayoung, Oh 20 Nov 2006
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SNU INC Lab. Contents Introduction Background Power consumption and conservation mechanisms MAC sublayer LLC sublayer Network layer Transport layer OS/middleware and application layers Summary
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SNU INC Lab. Introduction Power management is one of the most challenging problem in wireless communication This paper addresses – Incorporation of energy conservation at all layers of the protocol stack for wireless networks
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SNU INC Lab. Background Wireless network architecture Protocol layers
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SNU INC Lab. Power consumption and conservation mechanisms(1) Sources of power consumption – Communication Transmit(1.5W)>receive(0.75W)>standby(0.01w) Goal is to optimize the transceiver usage – Computation Protocol processing aspects – Ex) usage of CPU and main memory, data compression.. Tradeoff btw communication costs and computation – communication costs computation needs Goal is to balance btw communication and computation
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SNU INC Lab. Power consumption and conservation mechanisms(2) General conservation guidelines and mechanisms – Network layer Balance the amount of traffic carried by each node – MAC layer : collisions should be eliminated Using a small packet size for registration and bandwidth request – Link layer Transmissions may be avoided when channel are poor Error control schemes (ARQ + FEC) – In a typical broadcast environment Broadcast a schedule that contains data transmission starting times for each mobile Turn off the transceiver whenever the node determines that it will not be receiving data for a period of time – In switching from transmit to receive modes, and vice versa Continuous allocation Aggregate packet requests
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SNU INC Lab. MAC sublayer(1) IEEE 802.11 standard – CSMA/CA (Collision Sense Multiple Access/Collision Avoidance) – For power conservation (QoS problem) A mobile – Active mode/Power Saving mode Base station – buffering for PS mode mobile – Per-packet energy consumption Energy cost = fixed cost (MAC operation) + incremental cost (packet size) Fixed cost of Unicast > Fixed cost of broadcast ∵ receiver’s CTS/AcK messages Incremental cost of Unicast = Incremental cost of broadcast
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SNU INC Lab. MAC sublayer(2) EC-MAC protocol (Energy Conserving) – Using centralized scheduler ∴ optimize the transmission schedule FSM-Frame synchronization message (BS->mobile)
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SNU INC Lab. MAC sublayer(3) PAMSA protocol (Power Aware Multi-Access) – For Ad hoc network – Separate channels to determine when and how long to power off RTS/CTS control packets Data packets 1. RTS Data A B Control channel Data channel 2. CTS X 2’. backoff 1. RTS Data A B 2. CTS 3. Data 4. transmits a “busy tone” over the control channel CC Do not overhear Turn off
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SNU INC Lab. LLC sublayer(1) Adaptive error control with ARQ ≠ ARQ (Automatic Repeat Request) – The new metric for energy efficiency total amount of data delivered,total energy consumed( 일정 ) – To maximize the energy efficiency of the protocol Avoid persistence in retransmission data Trade off # of retransmission attempts for probability of successful transmission Inhibit transmission when channel conditions are poor ARQ works as normal until the transmitter detects an error (lack of AcK) ARQ enters a probing mode (a probing packet is transmitted every t slots) until a properly received AcK is encountered
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SNU INC Lab. LLC sublayer(2) Adaptive error control with ARQ+FEC (Forward Error Correction) – To keep energy consumption at a minimum The error control scheme associated with each stream may need to be modified as channel conditions change – Certain setup parameters and a channel model Packetsize, QoS requirements (used by MAC sublayer) and packet scheduler are associated with each data stream
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SNU INC Lab. Network layer(1) Typical routing algorithms for Ad hoc – Frequent topology updates Improved routing but consume precious bandwidth – Infrequent topology updates Decrease update messages but inefficient routing Typical metrics – Shortest-hop, shortest-delay, and locality stability In wireless additional metrics – Energy resources, network life time
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SNU INC Lab. Network layer(2) Unicast traffic – A shortest-hop routing (x), A shortest-cost routing (o) 1. Energy consumed per packet – Total energy consumed is also minimized 2. Variance in power levels across mobiles – All mobiles are equal 3. Cost per packet – Metrics other than energy consumed per packet – Mobiles with depleted energy do not lie on many routes 4. Maximum mobile cost – By minimizing the cost per mobile
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SNU INC Lab. Network layer(3) Broadcast traffic – Each mobile’s radio turns off after receiving a packet if its neighbors have already received a copy of the packet – Power-aware broadcast tree approach The tree is constructed starting from a source and expanding to the neighbors – have consumed lower amounts of power – have not already received the data transmission
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SNU INC Lab. Transport layer(1) TCP degrades significantly over a wireless link (handoff) – A larger # of retransmissions – Frequently invoke congestion control measures throughput, delay, energy consumption Three schemes for reducing retransmission – Split connection protocols – Link layer approach (ex: ARQ+FEC) – End-to-End protocol
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SNU INC Lab. Transport layer(2) Energy consumption analysis of TCP – The average # of successes per transmission attempt – Error correlation – Congestion control of TCP By backing off and waiting during error bursts – TCP Probing A probe cycle is initiated during error instead of congestion control – If persistent error conditions are detected Sender invokes standard TCP congestion control – If transient random error Sender resumes transmission using available network bandwidth
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SNU INC Lab. OS/middleware and application layers(1) OS/middleware for energy efficiency – Mobility impacts the design of OS, middleware – Mobile computers’ processing is expensive (battery power) – Architecture techniques pipelining and parallelism – Predictive shutdown during periods of inactivity – Separation both computation activity (External events) and inactivity
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SNU INC Lab. OS/middleware and application layers(2) Application layer for energy efficiency – Load partitioning Selectively partitioned btw the mobile and base station – Mobile host : display, acquire multimedia data – Base station : Intensive computations – Proxies Middleware automatically adapt the applications to changes in battery power and bandwidth – Databases Access time (probe wait, bcast wait) minimization – Video processing Under severe bandwidth constraints or low-power situations – Carefully discarding selected packets – Decreasing the # of transmitted bits
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SNU INC Lab. Conclusions The key to energy conservation in wireless communications – Network layer Balance the amount of traffic carried by each node – Link layer Transmissions may be avoided when channel are poor Error control schemes (ARQ + FEC) – MAC layer : collisions should be eliminated Using a small packet size for registration and bandwidth request
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SNU INC Lab. References CE. Jones, et al, "A Survey of Energy Efficient Network Protocols for Wireless Networks”, Wireless Networks, 2001.
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