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1 Active Probing for Available Bandwidth Estimation Sridhar Machiraju UC Berkeley OASIS Retreat, Jan 2005 Joint work with D.Veitch, F.Baccelli, A.Nucci,

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Presentation on theme: "1 Active Probing for Available Bandwidth Estimation Sridhar Machiraju UC Berkeley OASIS Retreat, Jan 2005 Joint work with D.Veitch, F.Baccelli, A.Nucci,"— Presentation transcript:

1 1 Active Probing for Available Bandwidth Estimation Sridhar Machiraju UC Berkeley OASIS Retreat, Jan 2005 Joint work with D.Veitch, F.Baccelli, A.Nucci, J.Bolot

2 2 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

3 3 Estimating Available Bandwidth Why –Path selection, SLA verification, network debugging, congestion control mechanisms How –Estimate cross-traffic rate and subtract from known capacity Use packet pairs –Estimate available bandwidth directly Use packet trains

4 4 Available Bandwidth Fluid Definition - spare capacity on a link In reality, we have a discrete system –Avail. b/w averaged over some time scale Capacity = 100Mbps 43 Mbps utilized ABW = 57Mbps Capacity = 100Mbps 43 Mbps utilized ABW = 57Mbps

5 5 t Packet Pair Methods Assume single FIFO queue of known capacity C –Queuing at other hops on path negligible Send packet pair separated by t Output separation t out depends on cross- traffic that arrived in t Capacity = 100Mbps 43 Mbps utilizedt out

6 6 Problem Statement What information about the cross- traffic do packet pair delays expose? Consider multi-hop case How to use packet pair in practice Might not apply in practice if Non-FIFO queuing Link layer multi-path

7 7 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

8 8 Small Probing Period t Assumption is that queue is busy between packets of pair Packet pair will not work for arbitrarily large t t Capacity = 100Mbps 43 Mbps utilizedt out

9 9 How Large Can t Be? First probe arrives at queue of size R Second probe arrives at queue of size S Cross-traffic arrives Queue empties after first probe t cannot be more than transmit time of first probe! Same packet pair delays –Different amounts of intervening cross-traffic First probe and some CT serviced

10 10 Tradeoffs Small enough t not possible/applicable in multi-hop path –Under-utilized link of lower capacity before bottleneck –Queue sizes of other hops comparable in magnitude to t Larger t can be used only if some assumption made about cross-traffic! –Independent increments, long range dependent

11 11 Problem Setup t-spaced packet pairs of size sz Consecutive delays R and S of probes –Delay is same as encountered queue size –Remove need for clock synchronization later A(T) is amount (service time) of cross- traffic arriving at (single) bottleneck in time T What can we learn about the probability laws governing A(T)?

12 12 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

13 13 Busy vs. Idle Queue First probe arrives at queue of size R Second probe arrives at queue of size S First probe and some CT serviced Cross-traffic arrives Queue empties after first probe queue is always busy queue is idle at least once

14 14 System equations Second delay, S is linearly related to first delay, R and amount of cross-traffic OR S is related only to amount of cross- traffic CT measured in time units of service time at bottleneck

15 15 A(t) and B(t) Bottleneck Output Link CT arrives on 4 links A(t)=4 B(t)=1 A(t)=4 B(t)=0 A(t)=4 B(t)=4 Periodic CT Burst after 1 st packetBurst before 2 nd packet Link 1 Link 2 Link 3 Link 4

16 16 CDF of A(t) Cumulative distribution of A(t) –Arrival process in t time units –Step function if similar amounts of cross- traffic arrives every time period of size t 0 1 Cumulative Distribution Function (CDF) A(t)

17 17 Joint Prob. Distribution of B(t),A(t) A(t), Arrival in t B(t), Burstiness within time t t 0 Low rate, low burstiness (few packets) High rate, high burstiness (many back to back packets) High rate, low burstiness (no back to back packets) A(t) > B(t) > A(t) – t (Density non-zero only in strip of size t) –B(t) depends on the capacity of link Given A(t), smaller B(t) implies A(t) amount of traffic is well-spread out within t time units

18 18 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

19 19 Solving System Equations Assumptions on CT needed for arbitrary t Our assumption on CT –A(t) is i.i.d. in consecutive time periods of size t –Traces from OC-3 (155Mbps link) at real router show that dependence between consecutive A(t) is 0.16 to 0.18 Given delays R and S of many packet pairs –Use conditional probabilities f r (s)=P(S=s|R=r)

20 20 Packet Pair Delays in (B,A) Space B(t), Burstiness within time t 0 Consecutive delays (r,s) occur because cross- traffic had (B,A) anywhere on a right angle f r (s)=P(S=s|R=r) is sum of (joint) probabilities along right angle s s-r-sz A(t), Arrival in t

21 21 Resolving Density in (B,A) Space B(t), Burstiness within time t 0 s s-r-sz A(t), Arrival in t Take packet pairs such that first delay R=r f r (s)=P(S=s|R=r) + Take packet pairs such that first delay R=r-1 f r-1 (s-1)=P(S=s-1|R=r-1) Take packet pairs such that first delay R=r f r (s-1)=P(S=s-1|R=r) + Take packet pairs such that first delay R=r+1 f r+1 (s)=P(S=s|R=r+1) s-1 _

22 22 Resolving Density in (B,A) Space B(t), Burstiness within time t 0 f r (s) + f r-1 (s-1) – f r (s-1) + f r+1 (s) –Difference in two densities adjacent along a diagonal Telescopic sum of differences along diagonal A(t), Arrival in t

23 23 Unresolvable Densities B(t), Burstiness within time t 0 Width of unresolvable strip is probe size, effect of probe intrusiveness Joint distribution also gives us CDF of A(t) A(t), Arrival in t

24 24 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

25 25 In Practice Absolute delays R and S not available Use minimum delay value observed and subtract from all observations –May not work if no probe finds all queues idle –Even capacity estimation may not work! Above limitations intrinsic to packet pair methods

26 26 Router traces of CT (utilization – about 50%) t is 1ms; each unit is 155Mbps*0.1ms bits Errors due to –Discretization –A(t) not entirely i.i.d. B B A A Estimation with Router Traces

27 27 Estimation of A(t) About 10-15% error, in general Larger errors with lower CT rates –larger delay values less likely Decreasing Cross-Traffic Rate Service time of cross-traffic arriving in 0.25, 1ms (milliseconds)

28 28 Outline Motivation Packet pair problem setup Describing the system Solving with i.i.d. assumption In practice Conclusions and future work

29 29 Conclusions and Future Work Packet pair methods for (single hop) avail. b/w work either with very small t (or) With assumptions on CT –I.I.D. assumption reasonable –Almost complete estimation possible –What other assumptions possible? Packet pair does not saturate any link –Hybrid of packet pair and saturating packet train methods?

30 30 Backup Slides

31 31 A(t) and B(t) Intervening cross-traffic A(t) (Arrival in t time units) B(t) (Arrival within t units) Periodic traffic of rate u.C u.tu.t-t Packet burst sized u.t after first packet u.t (Size of burst) Size of burst - t Packet burst sized u.t just before 2 nd pkt. u.t (Size of burst) Size of burst

32 32 Using conditional probabilities f r (s)=P(S=s|R=r) is a right angle F r (s)=P(S s|R=r) is a rectangle Horizontal bar is difference between rectangles Density in the (B,A) space is the difference between two horizontal bars

33 33 Required Delays for Estimation Increasing delays Ambiguities of size sz still allow the resolution of distribution of A(t)

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