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Towards Efficient and Robust Multihop Wireless Networks with Real-Time Media-Rich Application Support Ph.D. Dissertation Proposal Kimaya Mittal Department of Computer Science University of California, Santa Barbara Introduction • Popularity of wireless networks – Homes, offices, universities, airports, malls – Largely access-point-based at present Access point Internet Wireless user devices Wireline connectivity Kimaya Mittal, Ph.D. Dissertation Proposal Introduction • Multihop wireless networks gaining attention Wireline connectivity Internet Stand-alone (Ad hoc) Extending Internet connectivity (Mesh) Kimaya Mittal, Ph.D. Dissertation Proposal Introduction • Multihop wireless networks – Benefits: • • • • Easy to deploy/extend Self-configuring Adaptive Cost-effective – Tremendous potential to be technology of choice for ubiquitous Internet access Kimaya Mittal, Ph.D. Dissertation Proposal Introduction • Popularity of real-time media-rich applications – VoIP, video streaming, gaming, videoconferencing, media-rich messaging • Must be supported by Internet access technology • Strict requirements – Minimum required throughput – Maximum tolerable delay and jitter Kimaya Mittal, Ph.D. Dissertation Proposal Our Vision Multihop wireless networks provide ubiquitous Internet connectivity and support diverse applications, including real-time media-rich applications, in an efficient and robust manner Our focus is on 802.11 and IP-based networks Kimaya Mittal, Ph.D. Dissertation Proposal Challenges • Differences between wireless and wired networks – Shared medium • Nodes sharing medium may be unable to communicate – – – – – High link error rates Significantly lower capacity Resource-constrained devices Mobility and dynamic topology Easily accessible to malicious attackers • Wired network solutions not always applicable Kimaya Mittal, Ph.D. Dissertation Proposal Wireless Transmission Characteristics V R T W P Q U S X Kimaya Mittal, Ph.D. Dissertation Proposal Wireless Transmission Characteristics Transmission range of P V R T W P Q U S X Kimaya Mittal, Ph.D. Dissertation Proposal Wireless Transmission Characteristics Transmission range of P V R T W P Q U S X Carrier-sense range of P Kimaya Mittal, Ph.D. Dissertation Proposal Wireless Transmission Characteristics V R T W P Q U S Carrier-sense range of P X Carrier-sense range of Q Kimaya Mittal, Ph.D. Dissertation Proposal Our Focus • Focus on addressing three key challenges – Shared medium – Significantly lower capacity – Easily accessible to malicious attackers • Motivation – Very important for realization of our vision – Previously-proposed solutions lacking – Significant scope for improvement Kimaya Mittal, Ph.D. Dissertation Proposal Shared Medium • • • • • Medium shared with carrier-sense neighbors (CSN) Not all CSN can directly communicate Potentially different view of medium at each CSN Medium management challenging Challenge for realization of vision: How can requirements of real-time media-rich applications be met? V R T Transmission range Carrier-sense range Q W P U S Kimaya Mittal, Ph.D. Dissertation Proposal X Low Capacity • Wireless bandwidth limited and shared • Multiple hops along path contend for medium access – Significant capacity drop • Hidden terminal and exposed terminal problems • Challenge for realization of vision: How can diverse applications be efficiently supported? Kimaya Mittal, Ph.D. Dissertation Proposal Accessibility to Malicious Attackers • Any device within range can gain access – Can become part of routing infrastructure • Security vulnerabilities in several protocols – Popular routing protocols (AODV, DSR) • Can be exploited for non-optimal performance and denial of service – Compromise of the routing protocol can have farreaching effects on entire network • Challenge for realization of vision: How can network be made robust? Kimaya Mittal, Ph.D. Dissertation Proposal Dissertation Goals • To contribute to the realization of our vision in the following areas: – Real-time media-rich application support – Efficient utilization of capacity – Robustness to malicious behavior Kimaya Mittal, Ph.D. Dissertation Proposal Contributions • Real-time media-rich application support – Perceptive Communication [Tridentcom 06] – PRP and RRT: Protocols for intra-flow contention calculation [Broadnets 04, MONET 06] • Efficient utilization of capacity – Improvement of 802.11 capacity utilization (Remaining work) – Leveraging mobility [Mobiquitous 04, WCMC Journal (submitted)] • Robustness to malicious behavior – Analysis of security vulnerabilities of popular routing protocols + secure routing protocol (ARAN) [ICNP 02, JSAC 05] Kimaya Mittal, Ph.D. Dissertation Proposal VISION Multihop wireless networks provide ubiquitous Internet connectivity and support diverse applications, including real-time media-rich applications, in an efficient and robust manner GOALS Real-time media-rich application support Efficient utilization of capacity CONTRIBUTIONS Intra-flow contention calculation Leveraging user mobility Authenticated routing Network Layer Perceptive communication Improvement of 802.11 capacity utilization MAC Layer Kimaya Mittal, Ph.D. Dissertation Proposal Robustness to malicious behavior VISION Multihop wireless networks provide ubiquitous Internet connectivity and support diverse applications, including real-time media-rich applications, in an efficient and robust manner GOALS Real-time media-rich application support Efficient utilization of capacity Robustness to malicious behavior CONTRIBUTIONS Intra-flow contention calculation Leveraging user mobility Authenticated routing Network Layer Perceptive communication Improvement of 802.11 capacity utilization MAC Layer Kimaya Mittal, Ph.D. Dissertation Proposal Remaining Work Perceptive Communication: Motivation • Medium-related operations at a node depend on/affect medium state at CSN • Need for communication among CSN V R T Transmission range P Carrier-sense range Q W U S Kimaya Mittal, Ph.D. Dissertation Proposal X Examples of Need for Communication Among CSN • Support of real-time media-rich applications requires – Admission control – Prioritized medium access • Need to share information such as bandwidth consumption and priorities of existing flows with CSN Kimaya Mittal, Ph.D. Dissertation Proposal Potential Approaches to Communicate Among CSN • Direct communication – Impossible (CS range > Tx range) • High-power transmission [Yang 03] – More energy, less spatial reuse • Multihop forwarding [Yang 03] – Requires relay node • Lower rate transmission code – May not be supported, may not reach all CSN Kimaya Mittal, Ph.D. Dissertation Proposal Potential Approaches to Communicate Among CSN • Direct communication CS range – Impossible (CS range > Tx range) Tx range • High-power transmission [Yang 03] R T – More energy, less spatial reuse Q P U • Multihop forwarding [Yang 03] – Requires relay node S • Lower rate transmission code – May not be supported, may not reach all CSN Kimaya Mittal, Ph.D. Dissertation Proposal Potential Approaches to Communicate Among CSN • Direct communication CS range – Impossible (CS range > Tx range) Tx range • High-power transmission [Yang 03] R T – More energy, less spatial reuse Q P U • Multihop forwarding [Yang 03] – Requires relay node S High power • Lower rate transmission code Tx range – May not be supported, may not reach all CSN Kimaya Mittal, Ph.D. Dissertation Proposal Potential Approaches to Communicate Among CSN • Direct communication CS range – Impossible (CS range > Tx range) Tx range • High-power transmission [Yang 03] R T – More energy, less spatial reuse Q P U • Multihop forwarding [Yang 03] – Requires relay node S • Lower rate transmission code – May not be supported, may not reach all CSN Kimaya Mittal, Ph.D. Dissertation Proposal Potential Approaches to Communicate Among CSN • Direct communication CS range – Impossible (CS range > Tx range) Tx range • High-power transmission [Yang 03] T R – More energy, less spatial reuse Q P U • Multihop forwarding [Yang 03] – Requires relay node S Lower rate • Lower rate transmission code Tx range – May not be supported, may not reach all CSN Kimaya Mittal, Ph.D. Dissertation Proposal Perceptive Communication • During transmission, change in carrier signal perceived by CSN • Certain characteristics can be detected – Duration of transmission – Silence between transmissions • Information encoded in perceivable characteristics – Can be inferred by CSN by monitoring carrier signal, packet need not be decoded Kimaya Mittal, Ph.D. Dissertation Proposal Detection of Perceptive Characteristics • Node records received signal strength (RSS) continuously (i.e. in every time slot) • Tracks signal strength over time • Identifies transmissions and silences from this information • Measures their durations Kimaya Mittal, Ph.D. Dissertation Proposal Detection of Transmission Duration • Idealized graph of signal strength vs. time • Packet Y sensed, not decoded • Duration of packet Y (Ty) perceived • Information encoded in and inferred from Ty RSS RxThresh CSThresh X Kimaya Mittal, Ph.D. Dissertation Proposal Y Ty time Detection of Silence Duration • Every transmission RSS preceded by preframe • Inter-frame space perceived, duration RxThresh (Ts) detected • Ts < Tdifs (inter-packet CSThresh space) • Information encoded in and inferred from Ts Pre-frame Inter-frame space Packet Inter-packet space Y Ts Kimaya Mittal, Ph.D. Dissertation Proposal Tdifs Time Application of Perceptive Communication • Application-specific codebook – Maps transmission durations or inter-frame space durations to meanings • Examples – Communication of identity through size of Hello messages • Size modified by appending ‘tail’ – Communication of packet priority through duration of inter-frame space Kimaya Mittal, Ph.D. Dissertation Proposal Testbed Evaluation • Motivation – Do actual graphs of signal strength vs. time resemble ideal graphs? – How accurately can perceptive characteristics be measured on wireless hardware? • Implementation – Prototype implementation on Mica2 mote • Only platform with API for per-slot RSS – RSSI sampling in alternate time slots Kimaya Mittal, Ph.D. Dissertation Proposal Simple Test Scenario • Single transmitter – Placed within few inches of receiver – Transmits 100 packets • 10 packets per second • 20 bytes payload • Single receiver – Samples RSS in every time slot – Processes RSS readings to identify transmissions • Simplistic algorithm – Infers payload size from detected transmission duration Kimaya Mittal, Ph.D. Dissertation Proposal Plot of RSSI vs. Time Ack Data Noise Kimaya Mittal, Ph.D. Dissertation Proposal Payload Size Detection in Simple Test Scenario Kimaya Mittal, Ph.D. Dissertation Proposal Analysis • All packets detected within +/- 2 bytes • 2-byte detection error unavoidable – RSSI sampling in alternate slots – Time slots of receiver and transmitter not perfectly synchronized • In remaining results, detection within +/2 bytes considered correct • Silence detection results similar Kimaya Mittal, Ph.D. Dissertation Proposal Experiment: Effect of Received Signal Strength • Experiment setup similar to simple test scenario • Magnitude of RSS varied by changing transmit power of sender Kimaya Mittal, Ph.D. Dissertation Proposal Effect of Received Signal Strength Kimaya Mittal, Ph.D. Dissertation Proposal Perceptive Communication: Conclusions • Perceptive communication among CSN feasible and effective on wireless hardware • Some error in detection unavoidable – Should be accounted for in protocol design • More sophisticated detection algorithm can further improve accuracy Kimaya Mittal, Ph.D. Dissertation Proposal Perceptive Communication: Impact • Powerful mechanism • Creates new possibilities for managing wireless medium • Several potential applications in prioritized MAC, admission control, bandwidth estimation, channel assignment, power control, etc. Kimaya Mittal, Ph.D. Dissertation Proposal Determination of Intra-Flow Contention: Motivation • Network capacity limited, may not be able to support all flows requesting access • Admission control necessary • Need to estimate bandwidth consumption of new flow for admission control decision • Non-trivial due to intra-flow contention Kimaya Mittal, Ph.D. Dissertation Proposal What is Intra-Flow Contention? • Nodes along a multihop path may lie within each other’s carrier-sense range • This leads to intra-flow contention Carrier-sensing range of node Y Z Y W Packets of flow F contend for medium access at nodes W, X and Y X Flow F Kimaya Mittal, Ph.D. Dissertation Proposal What is Intra-Flow Contention? • Due to intra-flow contention, bandwidth consumption of a flow at a node becomes a multiple of that requested by the application Carrier-sensing range of node Y Z Y W X Bandwidth consumed by flow F at nodes W, X, Y each is 3 times the single-hop bandwidth Flow F Kimaya Mittal, Ph.D. Dissertation Proposal Contention Count • Contention Count (CC) at a node = Intersection of (set of carrier-sensing neighbors) with (set of nodes on multihop path) + 1 • Bandwidth consumption of flow = CC x (single-hop bandwidth consumption) • To estimate bandwidth consumption, CC must be calculated Kimaya Mittal, Ph.D. Dissertation Proposal Calculation of Contention Count • Previous approaches – Contention-Aware Admission Control (CACP) [Yang et al. 03] • High power transmissions to communicate with CSN • Our approaches – Pre-Reply Probe (PRP) and Route Request Tail (RRT) – Use our perceptive communication techniques to communicate with CSN – Integrated with reactive route discovery Kimaya Mittal, Ph.D. Dissertation Proposal Comparison of PRP/RRT with CACP • Main benefits – Reduced energy consumption – Reduced network overhead • Main drawback – Error in CC calculation when collisions occur (No more than +/- 1 in our simulations) Kimaya Mittal, Ph.D. Dissertation Proposal Remaining Work: Improving Capacity Utilization of 802.11 • Hidden terminal and exposed terminal problems well-known artifacts of CSMA protocols • Result in wasted network capacity Kimaya Mittal, Ph.D. Dissertation Proposal What are Hidden Terminals? Carrier-sense range P Q S R Nodes P and R cannot carrier sense each other and transmit simultaneously, causing collisions at one or both receivers Kimaya Mittal, Ph.D. Dissertation Proposal What are Exposed Terminals? Carrier-sense range Q S P R Nodes P and R cannot transmit simultaneously due to carrier sensing, even though their transmissions do not mutually interfere Kimaya Mittal, Ph.D. Dissertation Proposal Hidden and Exposed Terminals • Hidden terminals waste capacity through collisions • Exposed terminals waste capacity through missed opportunities to transmit • Prevalence of hidden and exposed terminals depends on topology and carrier sense range – Large CS range => More exposed terminals – Small CS range => More hidden terminals – Inherent tradeoff Kimaya Mittal, Ph.D. Dissertation Proposal Alleviation of Hidden and Exposed Terminals: Previous Work • RTS/CTS – Does not address exposed terminals • Adjusting CS range – Eliminating hidden terminals [Chakeres 04, Fuemmeler 04] – Reducing exposed terminals [Vasan 05] – Achieving optimal balance [Zhai 06, Zhu 06] Kimaya Mittal, Ph.D. Dissertation Proposal Proposed Contribution • Can a solution be designed to eliminate both hidden and exposed terminals simultaneously? – Adjustment of CS range clearly not enough • Proposed Approach – Set CS range to sufficiently large value to eliminate hidden terminals – Modify protocol to discover and alleviate exposed terminals Kimaya Mittal, Ph.D. Dissertation Proposal Challenges • Detection of exposed terminals – Distance-based assumptions naïve • Keeping information up-to-date – Interference characteristics may vary with time • Coordination of simultaneous transmissions Kimaya Mittal, Ph.D. Dissertation Proposal Potential benefit • Qualnet simulation of random topology of 20 nodes in a 600m x 600m area shows 90 pairs of mutually exposed links – This is without increasing CS range to avoid hidden terminals – Hardware limitations currently prevent testbed evaluation • Indicates potential benefit of proposed approach Kimaya Mittal, Ph.D. Dissertation Proposal VISION Multihop wireless networks provide ubiquitous Internet connectivity and support diverse applications, including real-time media-rich applications, in an efficient and robust manner GOALS Real-time Efficient Robustness media-rich utilization of to malicious application capacity behavior support CONTRIBUTIONS Intra-flow contention calculation Leveraging user mobility Authenticated routing Network Layer Perceptive communication MAC Layer Improvement of 802.11 capacity utilization Conclusions • Dissertation contributes towards solving important problems towards realization of our vision • Significantly advances stateof-the-art • Creates new avenues for further research Kimaya Mittal, Ph.D. Dissertation Proposal Thank You! 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