Achieving a Realistic Notion of Time in Discrete Event Simulation

Gaderer, Georg; Nagy, Anetta; Loschmidt, Patrick; Sauter, Thilo

doi:10.1155/2011/294852

Cited by 16 publications

(7 citation statements)

References 19 publications

(26 reference statements)

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“…Since ω γ T (·) = 0, (2) and (3) are equal to those reported in [5]. The values of σ 2 θ and σ 2 γ are typical of an AT-cut XO of medium stability and they have been calibrated in order to obtain a slightly bigger Allan variance than the one reported in [27] and [28]. 2) Temperature (T ): The frequency skew due to temperature (ω γ T (·) = 0) is the only effect on quartz stability (σ 2 θ = 0 and σ 2 γ = 0 ).…”

Section: A State Parametersmentioning

confidence: 97%

Approximating Optimal Estimation of Time Offset Synchronization With Temperature Variations

Mongelli

Scanzio

2014

IEEE Trans. Instrum. Meas.

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This paper addresses the problem of time offset synchronization in the presence of temperature variations, which lead to a non-Gaussian environment. In this context, regular Kalman filtering reveals to be suboptimal. A functional optimization approach is developed in order to approximate optimal estimation of the clock offset between master and slave. A numerical approximation is provided to this aim, based on regular neural network training. Other heuristics are provided as well, based on spline regression. An extensive performance evaluation highlights the benefits of the proposed techniques, which can be easily generalized to several clock synchronization protocols and operating environments.

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Section: A State Parametersmentioning

confidence: 97%

Approximating Optimal Estimation of Time Offset Synchronization With Temperature Variations

Mongelli

Scanzio

2014

IEEE Trans. Instrum. Meas.

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“…Since the advent of distributed systems, clock synchronization issues arise from inevitable clock drifts that are difficult to model and correct [18]. Inherent errors stem from the message delay through the network.…”

Section: Network Synchronizationmentioning

confidence: 99%

Low Complexity UWB Radios for Precise Wireless Sensor Network Synchronization

Carbone

Cazzorla

Ferrari

et al. 2013

IEEE Trans. Instrum. Meas.

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Wireless sensor networks are becoming widely diffused because of the flexibility and scalability they offer. However, distributed measurements are significant only if the readout is coupled to time information. For this reason, network-wide time synchronization is the main concern. The objective of this paper is to exploit a very simple hardware implementation of an IR-UWB radio for realizing an accurate synchronization system for wireless sensors. The proposed solution relies on commercial-off-the-shelf discrete electronic components (rather than on specialized transceivers). It is designed for providing accurate timestamping of the packet time of arrival (TOA) to an adder-based tunable clock, which tracks the network time reference. The comprehensive set of experimental results based on prototypes, shows a TOA detection error with a standard deviation well below 1 ns. On the other hand, in the FPGAbased prototype, the synchronization performance reaches an overall synchronization error of few nanoseconds. Finally, in order to highlight the tradeoff between timestamping accuracy, clock stability, and synchronization performance, some additional simulations have been carried out: a synchronization error in the order of 1 ns is possible, if good local oscillator sources are available in the nodes and if the adjustable clock has a sufficient resolution.

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“…Although these phenomena could be measured and (in theory) corrected by using a suitable model, the problem is a substantial stochastic component in the oscillator behavior that cannot be compensated. A thorough analysis is reported in [21], while an accurate oscillator model for use in discrete-event simulators is presented in [22]. For this reason, rate deviations cannot be evaluated and compensated once for all.…”

Section: Compensation Of Clock Deviationsmentioning

confidence: 99%