Enhancing Accuracy and Robustness of Frequency Transfer Using Synchronous Ethernet and Multiple Network Paths

Rizzi, Mattia; Rinaldi, Stefano; Ferrari, Paolo; Flammini, A.; Fontanelli, Daniele; Macii, David

doi:10.1109/tim.2016.2559950

Cited by 9 publications

(1 citation statement)

References 41 publications

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“…In some instances (e.g., the White Rabbit project [9]), they are implemented through different means. Accurate frequency transfer can be realized at the physical level by means of Synchronous Ethernet [10], provided node clocks throughout the network satisfy suitably tight conditions on frequency accuracy [11]. In this paper we focus on the problem of frequency transfer and the achievement of frequency synchronization by the exchange of packets with embedded timestamps.…”

Section: Introductionmentioning

confidence: 99%

Precision Packet-Based Frequency Transfer Based on Oversampling

Giorgi

Narduzzi

2017

IEEE Trans. Instrum. Meas.

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Frequency synchronization of a distributed measurement system requires the transfer of an accurate frequency reference to all nodes. The use of a general-purpose, packetbased network for this aim is analyzed in the paper, where oversampling is considered as a means to counter the effects of packet delay variation on time accuracy. A comprehensive analysis, that includes the stability of the local clock, is presented and shows that frequency transfer through a packet network of this kind is feasible, with an accuracy level that can be of interest to a number of distributed measurement applications.

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Section: Introductionmentioning

confidence: 99%

Precision Packet-Based Frequency Transfer Based on Oversampling

Giorgi

Narduzzi

2017

IEEE Trans. Instrum. Meas.

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An efficient genetic algorithm for large-scale planning of dense and robust industrial wireless networks

Gong

David

Tanghe

et al. 2018

Expert Systems with Applications

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An industrial indoor environment is harsh for wireless communications compared to an office environment, because the prevalent metal easily causes shadowing effects and affects the availability of an industrial wireless local area network (IWLAN). On the one hand, it is costly, time-consuming, and ineffective to perform trial-and-error manual deployment of wireless nodes. On the other hand, the existing wireless planning tools only focus on office environments such that it is hard to plan IWLANs due to the larger problem size and the deployed IWLANs are vulnerable to prevalent shadowing effects in harsh industrial indoor environments. To fill this gap, this paper proposes an overdimensioning model and a genetic algorithm based over-dimensioning (GAOD) algorithm for deploying large-scale robust IWLANs. As a progress beyond the state-of-the-art wireless planning, two full coverage layers are created. The second coverage layer serves as redundancy in case of shadowing. Meanwhile, the deployment cost is reduced by minimizing the number of access points (APs); the hard constraint of minimal inter-AP spatial separation avoids multiple APs covering the same area to be simultaneously shadowed by the same obstacle. The computation time and occupied memory are dedicatedly considered in the design of GAOD for large-scale optimization. A greedy heuristic based over-dimensioning (GHOD) algorithm and a random OD algorithm are taken as benchmarks. In two vehicle manufacturers with a small and large indoor environment, GAOD outperformed GHOD with up to 20% less APs, while GHOD outputted up to 25% less APs than a random OD algorithm. Furthermore, the effectiveness of this model and GAOD was experimentally validated with a real deployment system.

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