1. Time Synchronization for Wireless Sensor Networks

2. Importance of timesync Internet Time Synchronization –Critical in some contexts (e.g. crypto, distributed packet traces) –A convenience in many other contexts Sensor Network Synchronization –Fundamental to its purpose: data fusion –Physical time needed to relate events in the physical world

3. Heterogeneity Time sync is critical at many layers –Beam-forming, localization, distributed DSP –Data aggregation & caching –TDMA guard bands –“Traditional” uses (debugging, user interaction…) But time sync needs are non-uniform –Maximum Error –Lifetime –Scope & Availability –Efficiency (use of power and time) –Cost and form factor

4. Beam-forming, localization, distributed Digital Signal Processing: small scope, short lifetime, high precision

5. t=3 t=2 t=1 t=0 Target tracking: larger scope, longer lifetime, but lower required precision

6. Isn’t this solved? NTP (Network Time Protocol) –Ubiquitous in the Internet –Variants appearing in sensor networks 802.11 synchronization –Precise clock agreement within a cluster GPS, WWVB, other radio time services High-stability oscillators (Rubidium, Cesium...)

7. So what’s wrong? This isn’t the Internet –Important assumptions no longer hold (fewer resources available for synchronization…) –Sensor apps have stronger requirements (…but we have to do better than the Internet anyway) Energy, energy energy: –Listening to the network is no longer free; even occasional CPU use can have a major impact Existing work is a critical building block BUT...

8. Infrastructure vs. Ad-Hoc “NTP provides UTC to the entire Internet” –But wait, you’re cheating! UTC is distributed to many places in the network out of band via various radio services (WWV, GPS, …) –Path from clients to a canonical clock is short Infrastructure isn’t ubiquitous in sensor nets –GPS doesn’t work indoors, in the forest, underwater, on Mars… What happens without infrastructure?

9. Poor Topologies Master Stratum 2 Stratum 3 ????? AC B Should A or C serve as B’s master? Either decision leads to poor sync with the other.

10. “Mundane” Reasons Cost –We can’t put a $500 Rubidium oscillator or a $50 GPS receiver on a $5 sensor node Form factor –Nodes are small, extra components are large Not actually a mundane limitation if it changes the economics of the sensor net

11. So what do we do? New architectural directions for time synchronization in sensor networks

12. Leveraging the Medium Wireless networks often use network interfaces with physical-layer broadcasts Reference Broadcast Synchronization takes advantage of this to remove most of the non-determinism from the critical path

13. 4 Time Components in Traditional sync SenderReceiver At the tone: t=1 NIC Physical Media NIC Send time Access Time Propagation Time Receive Time Problem: Many sources of unknown, nondeterministic latency between timestamp and its reception

14. Reference Broadcasts SenderReceiver NIC Physical Media NIC Propagation Time Receive Time Sync 2 receivers with each other, NOT sender with receiver Receiver NIC I saw it at t=4 I saw it at t=5

15. NIC Sender Receiver 1 Receiver 2 Critical Path NIC Sender Receiver Critical Path Time RBS reduces error by removing much of it from the critical path Traditional critical path: From the time the sender reads its clock, to when the receiver reads its clock RBS: Only sensitive to the differences in receive time and propagation delay

16. Receiver Determinism 1st testbed: Berkeley motes with narrowband (19.2K) radios

17. Time

18. Comparison to NTP Second implementation: –Compaq IPAQs (small Linux machines) –11mbit 802.11 PCMCIA cards Ran NTP, RBS-Userspace, RBS-Kernel –NTP synced to GPS clock every 16 secs –NTP with phase correction, too; it did worse (!) In each case, asked 2 IPAQs to raise a GPIO line high at the same time; differences measured with logic analyzer

19. “Here 0 sec after blue pulse!” “Here 1 sec after blue pulse!” “Here 3 sec after red pulse!” “Here 1 sec after red pulse!” Multi-Hop RBS Some nodes broadcast RF synchronization pulses Receivers in a neighborhood are synced by using the pulse as a time reference. (The pulse senders are not synced.) Nodes that hear both can relate the time bases to each other “Red pulse 2 sec after blue pulse!”

20. 1 3 2 A 4 8 C 5 7 6 B 10 D 11 9 1 3 2 4 8 5 7 6 1011 9 Time Routing The physical topology can be easily converted to a logical topology; links represent possible clock conversions Use shortest path search to find a “time route”; Edges can be weighted by error estimates

21. Multi-Hop RBS 1.85 +/- 1.28 2.73 +/- 1.91 2.73 +/- 2.42 3.68 +/- 2.57 Error (and std dev) over multiple hops, in usec

22. Most protocols stay synced all the time Post-facto sync: –Clocks start out unsynchronized –A set of receivers waits for an interesting event –Locally timestamp an event when it happens –After the fact, reconcile clocks Avoids wasting energy on unneeded sync; it’s easier to predict the past than future “Post-Facto” Sync

23. Post-Facto Sync Test pulses Sync pulses Drift Estimate 7usec error after 60 seconds of silence

24. Applications A few brief anecdotes

25. Acoustic Localization

26. Correlation Green is reference, Red is measured –Signals aligned to offset yielding max correlation Time in Samples (20 uS) Amplitude

27. Lessons Learned What’s the big picture?

28. We need many methods Time Sync Parameter Space: (max error, lifetime, scope, etc.) Application Requirement Available Sync Methods Better Goal: make the set rich enough to minimize waste

29. We need many methods Time Sync Parameter Space: (max error, lifetime, scope, etc.) Application Requirement Better Goal: make the set rich enough to minimize waste Ideally, methods should be tunable

30. A new service model Traditional time synchronization: “What time is it”? –Forces clocks to be synchronized all the time –Forces synchronization to pick one timescale Our new model: explicit conversions –What time is it here? –For a given time here, what’s the time there? This model buys us enormous freedom!

31. No global timescale AC B Your clock is your clock. Just know how your clock relates to others.

32. Future Work RBS is “under-specified” -- Who broadcasts? How is information disseminated? –Are there standard, easily configured solutions? Can we exploit global knowledge? –Initial work by Karp, Shenker is promising Is post-facto sync really practical? –Does it save enough energy and have a low enough cost in lost precision?

33. Summary Time sync is critical for sensor networks Existing solutions are inadequate: insufficient precision, wasteful of energy Fruitful new ideas have come about that never would have developed in the Internet: –Leverage the broadcast channel –Use local timescales –Sync after the fact A new service model is more expressive New field = new problems = new solutions!