Countermeasure for Time Synchronization Error of Phasor data between Substations Based on Estimated Transmission Line Constant

In this paper, the effect of time synchronization error on protection algorithms are studied for the usage of the LAN-based collaborative protection. In order to derive the effect of time synchronization, this paper proposes a substation model which is constructed with IEEE 1588 Precision Time Protocol (PTP) supported intelligent electronic devices. The proposed model is used as an example of a target platform to study the effect of time synchronization error with two typical substation protection algorithms, i.e., current differential-based substation protection and distance protection algorithms. From the analyzed and the simulated results, it was well observed that time synchronization error is a significant error-causing factor for both protection algorithms, resulting in erroneous detection of faults and erroneous estimation of fault distances, respectively. The results of research performed in this paper are expected to provide a good guide for constructing the future LAN-based digital power substation with precise time synchronization.

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A New Finite-Time Observer for Nonlinear Systems: Applications to Synchronization of Lorenz-Like Systems

The Scientific World JOURNAL ◽

10.1155/2016/8342089 ◽

2016 ◽

Vol 2016 ◽

pp. 1-7 ◽

Cited By ~ 2

Author(s):

Ricardo Aguilar-López ◽

Juan L. Mata-Machuca

Keyword(s):

Nonlinear Systems ◽

Control Theory ◽

Finite Time ◽

Numerical Experiments ◽

Time Synchronization ◽

Upper Bounds ◽

Observer Design ◽

Synchronization Error ◽

Chaotic Oscillator ◽

Chaotic Oscillators

This paper proposes a synchronization methodology of two chaotic oscillators under the framework of identical synchronization and master-slave configuration. The proposed methodology is based on state observer design under the frame of control theory; the observer structure provides finite-time synchronization convergence by cancelling the upper bounds of the main nonlinearities of the chaotic oscillator. The above is showed via an analysis of the dynamic of the so called synchronization error. Numerical experiments corroborate the satisfactory results of the proposed scheme.

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Impact of time synchronization error on the mode-shape identification and damage detection/localization in WSNs for structural health monitoring

Journal of Network and Computer Applications ◽

10.1016/j.jnca.2017.01.004 ◽

2017 ◽

Vol 83 ◽

pp. 181-189 ◽

Cited By ~ 4

Author(s):

Abderrazak Abdaoui ◽

Tarek M. El Fouly ◽

Mohamed H. Ahmed

Keyword(s):

Structural Health Monitoring ◽

Damage Detection ◽

Mode Shape ◽

Health Monitoring ◽

Time Synchronization ◽

Synchronization Error ◽

Shape Identification ◽

Structural Health

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Clock Drift Management Using Nature Inspired Algorithms

Journal of Information Technology Research ◽

10.4018/jitr.2012100104 ◽

2012 ◽

Vol 5 (4) ◽

pp. 48-62

Author(s):

Prakash Tekchandani ◽

Aditya Trivedi

Keyword(s):

Wireless Sensor Networks ◽

Sensor Networks ◽

Time Synchronization ◽

Synchronization Error ◽

Wireless Sensor ◽

Clock Skew ◽

Clock Drift ◽

Distributed Sensor ◽

Network Applications ◽

Nature Inspired Algorithms

Time Synchronization is common requirement for most network applications. It is particularly essential in a Wireless Sensor Networks (WSNs) to allow collective signal processing, proper correlation of diverse measurements taken from a set of distributed sensor elements and for an efficient sharing of the communication channel. The Flooding Time Synchronization Protocol (FTSP) was developed explicitly for time synchronization of wireless sensor networks. In this paper, we optimized FTSP for clock drift management using Particle Swarm Optimization (PSO), Variant of PSO and Differential Evolution (DE). The paper estimates the clock offset, clock skew, generates linear line and optimizes the value of average time synchronization error using PSO, Variant of PSO and DE. In this paper we present implementation and experimental results that produces reduced average time synchronization error using PSO, Variant of PSO and DE, compared to that of linear regression used in FTSP.

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Analysis and Compensation of Time Synchronization Error on SAR Image

Journal of the Korean Society for Aeronautical & Space Sciences ◽

10.5139/jksas.2020.48.4.285 ◽

2020 ◽

Vol 48 (4) ◽

pp. 285-293

Author(s):

Soojeong Lee ◽

Woo Jung Park ◽

Chan Gook Park ◽

Jong-Hwa Song ◽

Chang-Sik Bae

Keyword(s):

Time Synchronization ◽

Synchronization Error ◽

Sar Image

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Time Synchronization Method Based on Real-Time Precise Point Positioning

10.5194/egusphere-egu2020-12206 ◽

2020 ◽

Author(s):

Daqian Lyu ◽

Tianbao Dong ◽

Fangling Zeng ◽

Xiaofeng Ouyang

Keyword(s):

Real Time ◽

Time Scale ◽

Precise Point Positioning ◽

Time Synchronization ◽

Synchronization Error ◽

Time Transfer ◽

The Real ◽

Local Clock ◽

Receiver Clock ◽

Clock Offset

Precise point positioning (PPP) technique is an effective tool for time and frequency applications. Using phase/code observations and precise products, the PPP time transfer allows an accuracy of sub-nanoseconds within a latency of several days. Although the PPP time transfer is usually implemented in the post-processing mode, using the real-time PPP (RT-PPP) technique for time transfer with the shorter latency remains attractive to time community. In 2012, the IGS (International GNSS Service) launched an open-access real-time service (RTS) project, broadcasting satellite orbit and clock corrections on the Internet, which enables PPP time transfer in the real-time mode. In this contribution, we apply the RT-PPP for high-precision time transfer and synchronization. The GNSS receiver is required to be equipped with an atomic clock as the external local clock. We use the RT-PPP technique to compute the receiver clock offset with respective to the GNSS time scale. On the basis of clock offsets, we steer the local clock by frequency adjustment method. In this way, all the local clocks are synchronized to the GNSS time scale, making local clocks synchronized with each other.The time scales of the RTS products are evaluated at first. Six kinds of the RTS products (IGS01, CLK10, CLK53, CLK80 and CLK93) on DOY220-247, 2019 are pre-saved to compute the receiver clock offsets. The clock offset with respect to the GPST (GPS Time) obtained from the IGS final product is applied as the reference. The standard deviations (STDs) of the clock offsets with respect to the reference are 0.63, 1.76, 0.28, 0.27 and 1.28 ns for IGS01, CLK10, CLK53, CLK80 and CLK93, respectively.Finally, we set up a hardware system to examine the validity of our time synchronization method. The baseline of the time synchronization experiment is about 5 m. The synchronization error of the 1 PPS outputs is precisely measured by the frequency counter. The STD of the 4-days results is about 0.48 ns. The peak-to-peak value of the synchronization error is about 2.5 ns.

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