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Energy-efficient Self-adapting Online Linear Forecasting for Wireless Sensor Network Applications

Energy-efficient Self-adapting Online Linear Forecasting for Wireless Sensor Network Applications. Jai-Jin Lim and Kang G. Shin Real-Time Computing Laboratory, Electrical Engineering and Computer Science University of Michigan, Ann Arbor, MI 48109 – 2122, USA

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Energy-efficient Self-adapting Online Linear Forecasting for Wireless Sensor Network Applications

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  1. Energy-efficient Self-adapting Online Linear Forecasting for Wireless Sensor Network Applications Jai-Jin Lim and Kang G. Shin Real-Time Computing Laboratory, Electrical Engineering and Computer Science University of Michigan, Ann Arbor, MI 48109–2122, USA Mobile Adhoc and Sensor Systems Conference, 2005. IEEE International Conference on

  2. Outline • Introduction • Related work • Motivation and problem • Design of energy-efficient self-adapting online linear forecast • Evaluation • Conclusion

  3. Introduction • Forecast or prediction is of fundamental importance to all sensor network applications and services, including network management, data aggregation and mining, object tracking, and environmental surveillance. • Forecast should be designed as a middleware component that is predictive, energy-efficient, and self-manageable

  4. Introduction • Predictive, a forecast method should predict as many future measurements as possible with the required forecast quality. • Energy-efficient, when the prediction logic is shared across networked sensors, a forecast method should reduce the number of measurements to be transmitted through the network. • Self-manageable, a forecast method should self adjust the model parameters based on the forecast errors observed during actual measurements.

  5. Introduction • We focus on linear forecast, as it has been widely used to characterize the time-series data for many data mining and feature extraction algorithm, which work on a series of piece-wise linear representations (PLRs) extracted from the underlying time-series data.

  6. Related work Distributed in-network aggregation and approximate monitoring in sensor networks. • To reduce the number of transmissions involved in a distributed in-network aggregation, the authors of [7] rely on an aggregation tree rooted at an aggregator. • The aggregated result is affected lot by packet loss over a lossy wireless channel. To remedy this problem, the authors of [12] proposed a new robust aggregation tree construction algorithm against packet loss over a wireless channel.

  7. Related workData mining and piece-wise linear representation • The authors of [6] compare different time-series representations over many real-world data in terms of reconstruction accuracy. They concluded that there is little difference among all well-known approaches in terms of theroot mean square error. • The authors of [5] undertook extensive review and empirical comparison of a variety of algorithms to construct a piece-wise linear representation from time-series data stored in data base systems. They also proposed the on-line bottom up piece-wise linear segmentation technique, called SWAB (Sliding Window And Bottom-up), that produces high-quality approximations.

  8. Motivation and problemA. Motivation • Initially, our desire for the method is generated by the need to design a unified in-network data aggregation and mining service, which extends the in-network data aggregation service in such a way that data mining queries are issued and processed within the same network. • Both aggregation service and data mining service need to collect continuous measurements, typically at periodic intervals, about various network states such as the temperature of some region and position/ orientation of moving targets, whose data type isnumeric in sensor networks.

  9. Motivation and problemA. Motivation • Aggregation results like AVG, SUM, MIN, and MAX, hide key information on gradual trends or patterns in measurements. • PLR will be appropriate as a basic representation of the network state for a unified in-network aggregation and data mining service. It used by many data mining applications, not only holds such patterns, but also reconstruct the original time-series within some error bound.

  10. Motivation and problemb. Problem statement • Design an energy-efficient self-adaptive online linear forecast method. • Given: • An time-series xi, i=1,2,… • forecast quality threshold ε • Minimizesthe number of trend changes under a given quality measure.

  11. Motivation and problemb. Problem statement • It will produce a sequence of piece-wise linear segments, where each piece-wise linear fit to the underlying original time-series data:

  12. Motivation and problemb. Problem statement

  13. Motivation and problemb. Problem statement • The forecast quality:

  14. Motivation and problemb. Problem statement • Since the solution should be • Energy-efficient: minimize the number of trend changes. • Lightweight: incur O(1) space and time overheads in extracting a trend. • Adaptive: self-adjust the model parameters. • On-line: there is no time lag.

  15. Design of energy-efficient self-adapting online linear forecast (A) preliminary • Least-Square-Error based forecast method (LSEL) • Non-seasonal Holt-Winters Linear forecast (NHWL) • Double-Exponential-Smoothing based Linear forecast (DESL)

  16. Least-Square-Error based forecast method (LSEL) • An intuitive approach to extracting linear trend information is to apply the linear regression method • Forecasting with the linear regression needs to identify the model parameters from past W measurements. • A w-period moving linear regression with O(W) space and time requirements is built as follows.

  17. Least-Square-Error based forecast method (LSEL) • Suppose [tb,te] is the interval for time series • Past W measurements of xi, i∈[tb,te] , W≡te-tb+1 , will be extract the parameters of a new liner trend[18] • The τ- step ahead linear forecast into future measurement after t is given by

  18. Non-seasonal Holt-Winters Linear forecast (NHWL) • A commonly-used linear trend forecast algorithm with O(1) space and time overheads is NHWL. • It use exponential smoothing to extract the model parameters of a linear trend. • NHWL uses separate smoothing parameters, α,β (0< α,β <1) for the intercept and the slope updates at time t.

  19. Non-seasonal Holt-Winters Linear forecast (NHWL) • The intercept and the slope update as follows: where the determination of smoothing parameters is left to the user or application. • The τ- step ahead linear forecast into future measurement after t is given by

  20. Double-Exponential-Smoothing based Linear forecast (DESL) • DESL has two major differences from two: • First, it only one single smoothing parameter. • Second, it minimizing the weight sum of squared errors, shown in[3] • Given a smoothing constant α, DESL requires that the exponential smoothing statistics are updated at every sampling period: where is a weighted average of all past observations,

  21. Double-Exponential-Smoothing based Linear forecast (DESL) • Then the intercept and the slope are known [3] • Thus, the τ- step ahead linear forecast into future measurement after t is given by

  22. Design of energy-efficient self-adapting online linear forecast (B) The proposed linear forecast method • Directly smoothed slope based linear forecast (DSSL) • Directly averaged slope based linear forecast (DASL)

  23. Directly smoothed slope based linear forecast (DSSL) • DSSL extends the interval of instantaneous slope calculation from between two successive sampling measurements to between two successive linear segments. • A slope estimate st is defined by

  24. Directly smoothed slope based linear forecast (DSSL) • Then, DSSL applies the same update procedures for slope and the intercept as in NHWL. • the τ- step ahead linear forecast into future measurement after t is given by

  25. Directly averaged slope based linear forecast (DASL) • A common problem with any exponential smoothing system is that it is difficult to determine an appropriate smoothing parameter. • DASL uses another incremental relationship using st • the τ- step ahead linear forecast into future measurement after t is given by

  26. Evaluation • We evaluate the proposed method over various real-world and synthetic time-series data.

  27. Communication overhead

  28. Mean absolute deviation

  29. Communication overhead of DSSL with variable α,β

  30. Conclusion • We propose new linear forecast method and evaluate the performance with existing well-known linear forecast methods. An extensive study based on both real-world data shows that the proposed methods reduce the number of trend changes by 20~50% compared to the other methods. • It is also shown that the performance of forecasting based on linear regression is not suitable both qualitatively and quantitatively. • Future work, TinyDB.

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