Your search keyword '"Space-time Coupling"' showing total 16 results

1. Dimensionless Analysis of the Spatial–Temporal Coupling Characteristics of the Surrounding Rock Temperature Field in High Geothermal Roadway Realized by Gauss–Newton Iteration Method.

Author

Zhou, Jiale, Zhang, Yuan, Shi, Peng, and Liu, Yang

Subjects

GAUSS-Newton method, HIGH temperatures, EMERGENCY management, THERMAL conductivity, SPATIOTEMPORAL processes

Abstract

Featured Application: This study is of great significance for identifying and understanding the spatio-temporal evolution of the temperature field of high geothermal surrounding rock and for effective risk and disaster management in deep mine exploration. Understanding the time–space coupling characteristics of the surrounding rock temperature field in high geothermal roadways is essential for controlling heat damage in mines. However, current research primarily focuses on individually analyzing the temperature changes in the surrounding rock of roadways, either over time or space. Therefore, the Gauss–Newton iteration method is employed to model the coupling relationship between temperature, time, and space. The results demonstrate that the dual coupling function describing the temperature field of the surrounding rock in both time and space provides a more comprehensive characterization of the temperature variations. Over time, as ventilation duration increases, the fitting degree of the characteristic curve steadily rises, and the characteristic curve descends overall. In the spatial dimension, the fitting degree of the characteristic curve gradually decreases with the rise of the dimensionless radius, and the characteristic curve ascends overall. Additionally, as thermal conductivity increases, the fitting degree of the characteristic curve steadily rises. [ABSTRACT FROM AUTHOR]

Published

2024

2. Anti-Eavesdropping by Exploiting the Space–Time Coupling in UANs.

Author

Wang, Yan, Ji, Fei, Guan, Quansheng, Zhao, Hao, Yao, Kexing, and Chen, Weiqi

Subjects

SPACETIME, EAVESDROPPING, ACCESS control

Abstract

Due to the space–time coupling access, we find that anti-eavesdropping opportunities exist in underwater acoustic networks (UANs), where packets can be successfully received only by the intended receiver, but collide at the unintended receivers. These opportunities are highly spatially dependent, and this paper studies the case that linearly deployed sensor nodes directly report data toward a single collector. We found an eavesdropping ring centered around these linearly deployed sensor nodes, where the eavesdropper could steal all the reported data. Since the typical receiving-alignment-based scheduling MAC (TRAS-MAC) will expose the relative spatial information among the sensor nodes with the collector, the eavesdropper can locate the eavesdropping ring. Although moving the collector into the one-dimensional sensor node chain can degrade the eavesdropping ring to a point that constrains the eavesdropping risk, the collector's location will be subsequently exposed to the eavesdropper. To efficiently protect the reported data and prevent the exposure of the collector's location, we designed a slotted- and receiving-alignment-based scheduling MAC (SRAS-MAC). The NS-3 simulation results showed the effectiveness of the SRAS-MAC and the TRAS-MAC in protecting data from eavesdropping, which protect 90% of the data from eavesdropping in the one-eavesdropper case and up to 80% of data from eavesdropping in ten-eavesdropper cases. Moreover, unlike TRAS-MAC, which will expose the collector's location, SRAS-MAC provides multiple positions for the collector to hide, and the eavesdropper cannot distinguish where it is. [ABSTRACT FROM AUTHOR]

Published

2024

3. Anti-Eavesdropping by Exploiting the Space–Time Coupling in UANs

Author

Yan Wang, Fei Ji, Quansheng Guan, Hao Zhao, Kexing Yao, and Weiqi Chen

Subjects

UANs, medium access control, space–time coupling, security, anti-eavesdropping, location privacy, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

Due to the space–time coupling access, we find that anti-eavesdropping opportunities exist in underwater acoustic networks (UANs), where packets can be successfully received only by the intended receiver, but collide at the unintended receivers. These opportunities are highly spatially dependent, and this paper studies the case that linearly deployed sensor nodes directly report data toward a single collector. We found an eavesdropping ring centered around these linearly deployed sensor nodes, where the eavesdropper could steal all the reported data. Since the typical receiving-alignment-based scheduling MAC (TRAS-MAC) will expose the relative spatial information among the sensor nodes with the collector, the eavesdropper can locate the eavesdropping ring. Although moving the collector into the one-dimensional sensor node chain can degrade the eavesdropping ring to a point that constrains the eavesdropping risk, the collector’s location will be subsequently exposed to the eavesdropper. To efficiently protect the reported data and prevent the exposure of the collector’s location, we designed a slotted- and receiving-alignment-based scheduling MAC (SRAS-MAC). The NS-3 simulation results showed the effectiveness of the SRAS-MAC and the TRAS-MAC in protecting data from eavesdropping, which protect 90% of the data from eavesdropping in the one-eavesdropper case and up to 80% of data from eavesdropping in ten-eavesdropper cases. Moreover, unlike TRAS-MAC, which will expose the collector’s location, SRAS-MAC provides multiple positions for the collector to hide, and the eavesdropper cannot distinguish where it is.

Published

2024

4. Dimensionless Analysis of the Spatial–Temporal Coupling Characteristics of the Surrounding Rock Temperature Field in High Geothermal Roadway Realized by Gauss–Newton Iteration Method

Author

Jiale Zhou, Yuan Zhang, Peng Shi, and Yang Liu

Subjects

high geothermal, surrounding rock temperature field, space–time coupling, dimensionless, Gauss–Newton iteration, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Understanding the time–space coupling characteristics of the surrounding rock temperature field in high geothermal roadways is essential for controlling heat damage in mines. However, current research primarily focuses on individually analyzing the temperature changes in the surrounding rock of roadways, either over time or space. Therefore, the Gauss–Newton iteration method is employed to model the coupling relationship between temperature, time, and space. The results demonstrate that the dual coupling function describing the temperature field of the surrounding rock in both time and space provides a more comprehensive characterization of the temperature variations. Over time, as ventilation duration increases, the fitting degree of the characteristic curve steadily rises, and the characteristic curve descends overall. In the spatial dimension, the fitting degree of the characteristic curve gradually decreases with the rise of the dimensionless radius, and the characteristic curve ascends overall. Additionally, as thermal conductivity increases, the fitting degree of the characteristic curve steadily rises.

Published

2024

5. Corrigendum: The behavior of partially coherent twisted space-time beams in atmospheric turbulence

Author

Milo Hyde

Subjects

atmospheric turbulence, coherence, random media, random fields, space-time coupling, spatiotemporal coupling, Physics, QC1-999

Published

2023

6. The behavior of partially coherent twisted space-time beams in atmospheric turbulence

Author

Milo W. Hyde IV

Subjects

atmospheric turbulence, coherence, random media, random fields, space-time coupling, spatiotemporal coupling, Physics, QC1-999

Abstract

We study how atmospheric turbulence affects twisted space-time beams, which are non-stationary random optical fields whose space and time dimensions are coupled with a stochastic twist. Applying the extended Huygens–Fresnel principle, we derive the mutual coherence function of a twisted space-time beam after propagating a distance z through atmospheric turbulence of arbitrary strength. We specialize the result to derive the ensemble-averaged irradiance and discuss how turbulence affects the beam’s spatial size, pulse width, and space-time twist. Lastly, we generate, in simulation, twisted space-time beam field realizations and propagate them through atmospheric phase screens to validate our analysis.

Published

2023

7. Spatial-temporal Coupling Association Analysis of Coal Mine Gas Accidents from 2010 to 2018

Author

WANG Wei, LI Yu, LI Xiangong

Subjects

coal mine gas accidents, classification statistic, space-time coupling, apriori algorithm, strong association rules, Mining engineering. Metallurgy, TN1-997

Abstract

To systematically analyze space-time coupling rules of coal mine gas accidents in China from 2010 to 2018, this paper analyzes the gas accidents in coal mine from time, space, gas types, accident types and so on. Through the analysis of the data, the results show that the most probable time to have gas accidents is from 11:00 to 12:00 a.m., tunneling working faces are the most possible scene of gas accidents, the highest prone of having gas accidents is that gas explosion accidents occupy the largest proportion of all the accidents in coal and gas outburst mines. The accidents are given in the form of code, so that strong association rules can be found in many association rules about accidents. And the most frequent item sets can be found after the introduction of Apriori algorithm, that is, emphasis should be placed on the prevention of gas explosion accident caused by illegal blasting in the tunneling working face of low gas mine in December.

Published

2020

8. Spectral interferometry for the complete characterisation of near infrared femtosecond and extreme ultraviolet attosecond pulses

Author

Wyatt, Adam Stacey and Walmsley, Ian A.

Subjects

535, Physical Sciences, Physics, Atomic and laser physics, spectral interferometry, spectral phase interferometry for direct electric-field reconstruction, high harmonic generation, spatially encoded arrangement, attosecond, femtosecond, space-time coupling

Abstract

This thesis describes methods for using spectral interferometry for the complete space-time characterisation of few-cycle near-infrared femtosecond pulses and extreme ultraviolet (XUV) attosecond pulses produced via high harmonic generation (HHG). Few-cycle pulses tend to exhibit one or more of the following: (1) an octave-spanning bandwidth, (2) a highly modulated spectrum and (3) space-time coupling. These characteristics, coupled with the desire to measure them in a single-shot (to characterise shot-to-shot fluctuations) and in real-time (for online optimisation and control) causes problems for conventional characterisation techniques. The first half of this thesis describes a method, based on a spatially encoded arrangement for spectral phase interferometry for direct electric-field reconstruction (SEA-SPIDER). SEA-SPIDER is demonstrated for sub-10fs pulses with a central wavelength near 800nm, a bandwidth over 350nm, and a pulse energy of several nano-Joules. In addition, the pulses exhibit a modulated spectrum and space-time coupling. The spatially-dependent temporal intensity of the pulse is reconstructed and compared to other techniques: interferometric frequency-resolved optical gating (IFROG) and spectral phase interferometry for direct electric field reconstruction (SPIDER). SEA-SPIDER will prove useful in both femtoscience, which requires accurate knowledge of the space-time character of few-cycle pulses, and in HHG, which requires the precise knowledge of the driving pulse for seeding into simulations and controlling the generation process itself. Pulses arising from HHG are known to exhibit significant space-time coupling. The second half of this thesis describes how spectral interferometry may be performed to obtain the complete space-time nature of these fields via the use of lateral shearing interferometry. Finally, it is shown, via numerical simulations, how to extend the SPIDER technique for temporal characterisation of XUV pulses from HHG by driving the process with two spectrally-sheared driving pulses. Different experimental configurations and their applicability to different laser systems are discussed. This method recovers the space-time nature of the harmonics in a single shot, thus reducing the stability constraint currently required for photoelectron based techniques and may serve as a complimentary method for studying interactions of XUV attosecond pulses with matter.

Published

2007

9. Space–Time Conservation Element and Solution Element Method

Author

Wen, Chih-Yung, Jiang, Yazhong, and Shi, Lisong

Subjects

Conservation element and solution element method, Computational Fluid Dynamics, Numerical Method, High-order Scheme, Space-time Coupling, Hyperbolic Conservation Laws, Shock Capturing, Staggered Mesh, Compressible Flow, Material Interface, Detonation Wave, Computational Aeroacoustics, CESE Method, Numerical Simulation, Unstructured Mesh, Discontinuity Capturing, Shock Wave, Multiphase Flow, Interfacial Instability, thema EDItEUR::P Mathematics and Science::PD Science: general issues::PDE Maths for scientists, thema EDItEUR::P Mathematics and Science::PH Physics::PHU Mathematical physics, thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TG Mechanical engineering and materials::TGM Materials science::TGMF Engineering: Mechanics of fluids, thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TR Transport technology and trades::TRP Aerospace and aviation technology

Abstract

This open access book introduces the fundamentals of the space–time conservation element and solution element (CESE) method, which is a novel numerical approach for solving equations of physical conservation laws. It highlights the recent progress to establish various improved CESE schemes and its engineering applications. With attractive accuracy, efficiency, and robustness, the CESE method is particularly suitable for solving time-dependent nonlinear hyperbolic systems involving dynamical evolutions of waves and discontinuities. Therefore, it has been applied to a wide spectrum of problems, e.g., aerodynamics, aeroacoustics, magnetohydrodynamics, multi-material flows, and detonations. This book contains algorithm analysis, numerical examples, as well as demonstration codes. This book is intended for graduate students and researchers who are interested in the fields such as computational fluid dynamics (CFD), mechanical engineering, and numerical computation.

Published

2023

10. Two-Stage Dynamic Reactive Power Dispatch Strategy in Distribution Network Considering the Reactive Power Regulation of Distributed Generations.

Author

Chen, Lijuan, Deng, Zhenli, and Xu, Xiaohui

Subjects

*VOLTAGE control, *CAPACITOR banks, *HEURISTIC, *MATHEMATICAL optimization, *ELECTRONIC control

Abstract

To solve the coordinated dispatch and time-space coupling problem in the distribution network with distributed generations (DGs), a novel two-stage (Heuristic search and Variable correction) dynamic reactive power dispatch strategy is proposed in this paper. Meanwhile, according to the analysis of Gauss-type and Z-type membership function, a new objective function is put forward to achieve the balance between network loss and voltage deviation. First, the pre-optimization is made in Niche genetic algorithm to coordinate on-load tap changer (OLTC), capacitor banks (CBs), and DGs. Second, the sequential fuzzy c-means (SFCM) based on artificial bee colony (ABC) algorithm is proposed and then the Heuristic search based on this method is used to formulate the day-ahead plans of OLTC and CBs. Finally, the dispatch plans of OLTC and CBs are applied to recalibrate the day-ahead dispatch plans of DGs. Comparing with existing schemes, strategies and optimization approaches based on diverse evaluation indicators, optimization results on IEEE 33-bus, IEEE 14-bus, and PG&E 69-bus test systems verify the practicality and efficiency of the proposed method. In addition, the effects on the optimization results with different adjustment step and action time of the discrete adjust devices are discussed by the IEEE 33-bus test system. [ABSTRACT FROM AUTHOR]

Published

2019

11. 源外远源油气藏的内涵和特征 ---以准噶尔盆地盆1井西富烃凹陷为例.

Author

潘建国, 黄林军, 王国栋, 郭娟娟, 马永平, and 罗昭洋

Subjects

HYDROCARBON reservoirs, GAS migration, NATURAL gas prospecting, PETROLEUM industry, RESERVOIRS, GAS condensate reservoirs

Abstract

Copyright of Natural Gas Geoscience is the property of Natural Gas Geoscience and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

12. Seismo-Electromagnetic Emissions Related to Seismic Waves can Trigger TLEs.

Author

Sorokin, Leonid V.

Subjects

*SEISMIC waves, *ELECTROMAGNETIC fields, *ELECTRIC interference, *EARTH movements, *SEISMOLOGY

Abstract

This paper deals with the rare high intensity electromagnetic pulses associated with earthquakes, whose spectrum signature differs from that of atmospherics produced by lightning discharges. On the basis of actual data records, cases of the generation of anomalous seismo-electromagnetic emissions are described. These natural sub-millisecond electromagnetic pulses were associated with the passage of seismic waves from earthquakes to Moscow, the place where the electromagnetic field observations were made. Space-time coupling has been revealed between exact seismic waves from the earthquakes, lightning triggering and Transient Luminous Events triggering. [ABSTRACT FROM AUTHOR]

Published

2009

13. Finite strain viscoelasticity: how to consistently couple discretizations in time and space on quadrature-point level for full order $$p \ge 2$$ and a considerable speed-up.

Author

Eidel, Bernhard, Stumpf, Felipe, and Schröder, Jörg

Subjects

*STRAINS & stresses (Mechanics), *VISCOELASTICITY, *DISCRETIZATION methods, *SPACETIME, *NUMERICAL integration, *ALGORITHMS

Abstract

In computational viscoelasticity, the spatial finite element discretization for the global solution of the weak form of the balance of momentum is coupled to the temporal discretization for solving local initial value problems (IVP) of viscoelastic flow. In this contribution we show that this global-local or space-time coupling is consistent, if the total strain tensor as the coupling quantity exhibits the same approximation order $$p$$ in time as the Runge-Kutta (RK) integration algorithm. To this end we construct interpolation polynomials, based on data at $$t_{n+1}$$, $$t_{n}$$, $$\ldots $$, $$t_{n+2-p}$$, $$p\ge 2$$, which provide consistent strain data at RK stages. This is a generalization of the idea proposed in (Eidel and Kuhn, Int J Numer Methods Eng 87(11):1046-1073, ). For lower-order strain interpolation, time integration exhibits order reduction and therefore low efficiency. For consistent strain interpolation, the adapted RK methods up to $$p=4$$ obtain full convergence order and thus approve the novel concept of consistency. High speed-up factors substantiate the improved efficiency compared with Backward-Euler. [ABSTRACT FROM AUTHOR]

Published

2013

14. Spatio–temporal coupling to create sub-femtosecond pulses

Author

TJ Hammond

Subjects

Physics, ultrafast nonlinear optics, business.industry, Temporal coupling, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, high harmonic generation, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optics, nonlinear pulse compression, space–time coupling, 0103 physical sciences, Femtosecond, 010306 general physics, 0210 nano-technology, business

Abstract

We use the confluence of two intensity-dependent processes—low-order harmonic generation and self-phase modulation—to spatio–temporally couple and compress few-cycle pulses to be sub-cycle in duration. These half-cycle transient fields self-focus in space and in time (increasing the peak field strength) and can generate isolated attosecond pulses. We explore some of the parameter spaces available to create these half-cycle transients and methods of improving the half-cycle contrast. We also discuss how these pulses can increase high harmonic generation efficiency in the water window.

Published

2017

15. Optiques pour les impulsions attosecondes

Author

Bourassin-Bouchet, Charles, Laboratoire Charles Fabry de l'Institut d'Optique / Scop, Laboratoire Charles Fabry de l'Institut d'Optique (LCFIO), Université Paris-Sud - Paris 11 (UP11)-Institut d'Optique Graduate School (IOGS)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut d'Optique Graduate School (IOGS)-Centre National de la Recherche Scientifique (CNRS), Université Paris Sud - Paris XI, and Franck Delmotte

Subjects

Aberrations géométriques, Impulsions XUV attosecondes, Post-compression d’impulsions, Attosecond XUV pulses, Space-time coupling, Geometric aberrations, Pulse compression, Caractérisation d’impulsions attosecondes, [PHYS.COND.CM-GEN]Physics [physics]/Condensed Matter [cond-mat]/Other [cond-mat.other], Miroirs multicouches XUV, Characterization of attosecond pulses, XUV multilayer mirrors, Couplages spatio-temporels

Abstract

The shortest flashes of light ever produced so far have durations of a few tens of attoseconds (1 as = 10-18 s), and can only be generated in the extreme ultraviolet spectral range (XUV). Developing optical components able to control and shape such attosecond radiation is crucial to generalize the use of these light pulses. This is the topic of this work.Attosecond pulses happen to be chirped due to the physical process used to generate them. This phenomenon leads to an increase in their duration. Consequently, we developed inversely chirped multilayer mirrors, allowing one to compress the pulses during their reflection off the mirrors. By measuring these reflected pulses, we observed for the first time such a compression of attosecond pulses. Moreover, we developed another set of multilayer mirrors theoretically able to compress pulses below 50 as. That is below the current pulse duration record.Furthermore, the measurement of these pulses requires that they be focussed into a spectrometer. However, typically used focusing mirrors can add geometric aberrations. By the use of numerical simulations and thanks to an analytic study, we showed that these aberrations could strongly distort the spatio-temporal structure of the pulses, and increase their duration. Moreover, we showed that this phenomenon was not taken into account by current attosecond pulse characterization techniques. This could lead to determining the pulse duration to be shorter than it actually is.; Les plus brefs flashs de lumière qui puissent être produits en laboratoire actuellement ont des durées de quelques dizaines d’attosecondes (1 as = 10-18 s), et ne peuvent être créés que dans le domaine extrême-ultraviolet (XUV). Le développement de composants optiques capables de contrôler et de mettre en forme ce rayonnement attoseconde est crucial pour permettre à ces impulsions de se généraliser. Cette thèse porte donc sur l’étude et la réalisation de tels composants.Les impulsions attosecondes ont la particularité de comporter une dérivée de fréquence intrinsèque au processus utilisé pour leur génération. Cela a pour effet d’augmenter leur durée. Nous avons donc développé des miroirs multicouches capables d’induire une dérive de fréquence opposée sur les impulsions s’y réfléchissant, permettant ainsi de les compresser. En caractérisant les impulsions attosecondes réfléchies par ces miroirs, nous avons pour la première fois observé une telle compression des impulsions attosecondes. Nous avons également développé des miroirs multicouches théoriquement capables de compresser des impulsions sous la barre symbolique des 50 as, soit en dessous du record actuel de durée d’une impulsion lumineuse.La mesure de ces impulsions requiert leur focalisation dans un spectromètre. Or les miroirs focalisants généralement utilisés peuvent très rapidement introduire des aberrations géométriques. A l’aide de simulations numériques et d’une étude analytique, nous avons montré que ces aberrations pouvaient très fortement déformer la structure spatio-temporelle des impulsions attosecondes, provoquant une augmentation de leur durée. Enfin, nous avons montré que ces effets n’étaient pas pris en compte par les techniques actuelles de caractérisation d’impulsions attosecondes, cela pouvant amener à mesurer une impulsion attoseconde plus courte qu’elle ne l’est en réalité.

Published

2011

16. Seismo-electromagnetic emissions related to seismic waves can trigger TLEs

Author

Sorokin L.V. and Sorokin L.V.

Abstract

This paper deals with the rare high intensity electromagnetic pulses associated with earthquakes, whose spectrum signature differs from that of atmospherics produced by lightning discharges. On the basis of actual data records, cases of the generation of anomalous seismoelectromagnetic emissions are described. These natural sub-millisecond electromagnetic pulses were associated with the passage of seismic waves from earthquakes to Moscow, the place where the electromagnetic field observations were made. Space-time coupling has been revealed between exact seismic waves from the earthquakes, lightning triggering and Transient Luminous Events triggering. © 2009 American Institute of Physics.