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Link Layer Multicasting with Smart Antennas: No Client Left Behind Souvik Sen, Jie Xiong, Rahul Ghosh , Romit Roy Choudhury Duke University. Wireless Multicast Use-Cases. Widely used service Interactive classrooms, Smart home, Airports … MobiTV, Vcast, MediaFlo …
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Link Layer Multicasting with Smart Antennas: No Client Left Behind Souvik Sen, Jie Xiong, Rahul Ghosh, Romit Roy Choudhury Duke University
Wireless Multicast Use-Cases • Widely used service • Interactive classrooms, Smart home, Airports … • MobiTV, Vcast, MediaFlo … • Single transmission to reach all clients
Motivation • Today: • Multicast rate dictated by rate of weakest client (1 Mbps) • Inefficient channel utilization • Goal: • Improve multicast throughput • Uphold same reliability 1 Mbps 5.5 Mbps 11 Mbps
Problem is Non-Trivial • Scattered clients, different channel conditions • Time-varying wireless channel • Absence of per-packet feedback 1 Mbps 5.5 Mbps 11 Mbps
Solution – also Non-Trivial 11 Mbps 1 Mbps • Low rate transmission leads to lower throughput • High rate transmission leads lower fairness Past research mostly assume omnidirectional antennas
Problem Validation through Measurements
Measurements in Duke Campus AP Clients
Measurements in Duke Campus AP AP Transmission @ 1 Mbps Clients Clients
Measurements in Duke Campus AP Transmission @ 2 Mbps Clients
Measurements in Duke Campus AP Transmission @ 5.5 Mbps Clients
Measurements in Duke Campus AP Transmission @ 11 Mbps Clients
Measurements in Duke Campus Delivery Ratio Client index Topologies are characterized by very few weak clients
Reality shadow regions Weak clients tend to be clustered over small regions
4 3 6 5 1 2 Intuition
4 3 6 5 1 2 Intuition 1 Mbps Omni
4 3 6 5 1 2 Intuition 11 Mbps Omni
4 3 6 5 1 2 Intuition 4 Mbps Directional 11 Mbps Omni
4 4 3 3 6 6 5 5 1 1 2 2 Intuition 4 Mbps Directional 11 Mbps Omni 1 Mbps Omni
Intuition to Reality Few directional transmissions to cover few clients
Challenges • Partitioning the client set with optimal omni and directional rates • Estimation of wireless channel • Providing a guaranteed packet delivery ratio
Proposed Protocol - BeamCast Link Quality Estimator BeamCast Retransmission Manager Multicast Scheduler
Link Quality Estimator (LQE) • How to estimate the “bottleneck” rate for each client? • Bottleneck rate = Max. rate to support a given delivery ratio • AP takes feedback from the clients periodically • LQE creates a database using the feedback • Bottleneck rates are updated by using this database
Link Quality Estimator (LQE) • Theoretical relationship between delivery ratio (DR) and SNR
Multicast Scheduler (MS) • How to determine optimal transmission schedule? • A schedule = 1 omni + many directional transmissions • Optimal schedule = Schedule with minimum transmission time • MS extracts distinct client data rates from feedback • We assume, • Beamforming rate = F x Omnidirectional rate ; F > 1
Multicast Scheduler (MS) How to determine optimal transmission rate for each beam?
Multicast Scheduler (MS) • Problem becomes harder with overlapping beams Beam1 9 Mbps 1 2 7 Mbps 5 11 Mbps 4 6 Mbps 3 Mbps Beam2 3 Beam4 Beam3
Multicast Scheduler (MS) • Problem becomes harder with overlapping beams Beam1 9 Mbps 1 2 7 Mbps 5 11 Mbps 4 6 Mbps 3 Mbps Beam2 3 Beam4
Multicast Scheduler (MS) • Problem becomes harder with overlapping beams Beam1 9 Mbps 1 2 7 Mbps 5 11 Mbps 4 6 Mbps 3 Mbps 3 Beam4 Beam3
Multicast Scheduler (MS) • Problem becomes harder with overlapping beams Beam1 @ 7 Mbps 9 Mbps 1 Beam4 @ 11 Mbps 2 7 Mbps 5 11 Mbps 4 6 Mbps 3 Mbps 3 Beam3 @ 3 Mbps Dynamic Programming used to solve the problem
Retransmission Manager • To cope with packet loss • Receives lost packet information from the clients periodically • Retransmits a subset of lost packets • Choose packets using a simple heuristic
Evaluation • Qualnet simulation • Comparison with Feedback enabled 802.11 • Main Parameters : • Dynamic channels : Rayleigh, Rician fading; External interference • Antenna beamwidth: 45o, 60o, 90o • Factor of rate improvement with beamforming: 3, 4 • Metrics : Throughput, Delivery Ratio, Fairness • Application specified Minimum Delivery Ratio: 90%
Multicast Throughput BeamCast performs better with increasing Fading !
Multicast Throughput Throughput decreases with increase in client density
Delivery Ratio Increased delivery ratio for all clients, hence, No Client Left Behind
Limitations • Switching delay has been assumed to be negligible • Rate reduction for both fading and interference • Requires link layer loss discrimination • Focuses on “one-AP-many-clients” scenario • Multi-AP environment will require coordination • Ideas can be extended to EWLAN architectures • Controller assisted scheduling – better interference mitigation
Conclusions • Opportunistic beamforming for wireless multicasting • Multiple high rate directional vs. a single omni transmission • Rate estimation, scheduling and retransmission to achieve high throughput at a specified delivery ratio • A potential tool for next generation wireless multicast
Smart Antennas in Multicast • Jaikeo et. al talk about multicasting in ad-hoc networks • Assume multi-beam antenna model • Provide an analysis for collision probability • Do not consider asymmetry in transmission range • Ge et. al characterize optimal transmission rates • -Discuss throughput and stability tradeoff • Papathanasiou et. al discuss multicast in IEEE 802.11n based network • Minimize total Tx power but still provides a guaranteed SNR • Assume perfect channel state information is available
System Settings • We assume IEEE 802.11 based WLANs • Beamforming antennas are mounted on access points (AP) • Clients are equipped with simple omnidirectional antennas • Clients are scattered around AP and remain stationary • Surrounding is characterized by wireless multipath and shadowing effects
System Settings • Antenna Model A • Improvement in data rate is possible • C = W log2 (1 + SINR) Higher with beamforming antennas
Fairness • Jain’s Fairness Index Both schemes are comparable
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