Your search keyword '"Complex number"' showing total 2,225 results

1. Phasors and Complex Number Mathematics.

Published

2015

2. A lower bound for the complex flow number of a graph: A geometric approach.

Author

Mattiolo, Davide, Mazzuoccolo, Giuseppe, Rajník, Jozef, and Tabarelli, Gloria

Abstract

Let r≥2 $r\ge 2$ be a real number. A complex nowhere‐zero r $r$‐flow on a graph G $G$ is an orientation of G $G$ together with an assignment φ:E(G)→C $\varphi :E(G)\to {\mathbb{C}}$ such that, for all e∈E(G) $e\in E(G)$, the Euclidean norm of the complex number φ(e) $\varphi (e)$ lies in the interval [1,r−1] $[1,r-1]$ and, for every vertex, the incoming flow is equal to the outgoing flow. The complex flow number of a bridgeless graph G $G$, denoted by ϕC(G) ${\phi }_{{\mathbb{C}}}(G)$, is the minimum of the real numbers r $r$ such that G $G$ admits a complex nowhere‐zero r $r$‐flow. The exact computation of ϕC ${\phi }_{{\mathbb{C}}}$ seems to be a hard task even for very small and symmetric graphs. In particular, the exact value of ϕC ${\phi }_{{\mathbb{C}}}$ is known only for families of graphs where a lower bound can be trivially proved. Here, we use geometric and combinatorial arguments to give a nontrivial lower bound for ϕC(G) ${\phi }_{{\mathbb{C}}}(G)$ in terms of the odd‐girth of a cubic graph G $G$ (i.e., the length of a shortest odd cycle) and we show that this lower bound is tight. This result relies on the exact computation of the complex flow number of the wheel graph Wn ${W}_{n}$. In particular, we show that for every odd n $n$, the value of ϕC(Wn) ${\phi }_{{\mathbb{C}}}({W}_{n})$ arises from one of three suitable configurations of points in the complex plane according to the congruence of n $n$ modulo 6. [ABSTRACT FROM AUTHOR]

Published

2024

3. Area–time–energy efficient architecture of CBNS‐based fast Fourier transform.

Author

Das, Kaushik, Harshavardhan Reddy, Eda, Mandal, Arpita, Nath Pradhan, Sambhu, and Bhattacharjee, Abhishek

Abstract

A new approach for implementing the fast Fourier transform (FFT) using complex binary number system (CBNS) is presented in this paper. The advantage of using CBNS is that instead of processing the real and imaginary parts of a complex number separately, we can process both as a single entity. A total of four FFT architectures have been developed, which are 16‐, 64‐, 256‐, and 1024‐point FFT architectures. The proposed FFT is designed using Verilog‐HDL and implemented using a Virtex‐7 field‐programmable gate array (FPGA). The maximum clock rate achieved by the proposed FPGA‐based design is 376.1 MHz. The FPGA resource utilization of the FFT is less than the state‐of‐the‐art FFT designs. An application‐specific integrated circuit (ASIC) for the FFT is also designed. The normalized energy per FFT of the proposed ASIC is 0.14 nJ, and the normalized area per FFT of the ASIC is 1.08 mm2 which is less than other existing designs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Optical Properties and Refractive Index of Wintertime Aerosol at a Highly Polluted North‐Indian Site.

Author

Kapoor, Taveen Singh, Phuleria, Harish C., Sumlin, Benjamin, Shetty, Nishit, Anurag, Gupta, Bansal, Mahak, Duhan, Sandeep Singh, Khan, Mohd Shahzar, Laura, Jitender Singh, Manwani, Pooja, Chakrabarty, Rajan K., and Venkataraman, Chandra

Subjects

ALBEDO, REFRACTIVE index, ATMOSPHERIC aerosol measurement, OPTICAL properties, CARBONACEOUS aerosols, AEROSOLS, ATMOSPHERIC aerosols

Abstract

Estimation of aerosol radiative forcing continues to suffer from large uncertainties, partially from a lack of observations of aerosol optical properties. Limited measurements of the atmospheric aerosol imaginary refractive index (iRI) have been made, especially in some of the world's most polluted regions. In this study, we measured aerosol optical and micro‐physical properties at a regional site, Rohtak, India, representative of polluted cities in the Indo‐Gangetic plains in northern India. The average PM2.5 measured during the campaign was 163 μg/m3 with a single‐scatter albedo of 0.7, indicating the presence of strongly absorbing aerosol components. Measurements of aerosol absorption, scattering, and particle number size distributions were used to estimate the effective refractive index using an established Mie inversion technique. The calculated iRI was spectrally invariant in the visible region with values ranging between 0.076 and 0.145. Brown carbon absorption, estimated using an existing Mie optimization method, ranged 34–88 Mm−1, with strongly absorbing mass absorption cross‐sections (∼1.9 m2/g). Higher iRI were observed during periods with higher brown carbon absorption, which are likely directly emitted from combustion sources. Low volatility organic carbon fractions dominated during these periods, with likely persistence of atmospheric absorption. The iRI values are at the upper end of previously reported ranges of urban aerosol iRI. In a sensitivity analysis to measured parameters, the absorption had the dominant effect on estimated iRI. Measured single scatter albedos, were lower than those from climate model simulations over the region, demonstrating the need for intrinsic property measurements to evaluate and constrain climate models. Plain Language Summary: Particles in the atmosphere, called aerosol, can absorb or reflect/scatter sunlight to heat or cool the atmosphere, depending upon their physical and chemical properties. Climate models try to simulate these properties to understand their effect on the climate. The strength of the absorption is determined by the size of the particle (generally the diameter) and its refractive index (a complex number) which is a material property. In this study, we measure the refractive index of atmospheric aerosol at Rohtak, which lies in the highly polluted Indo‐Gangetic plains in India. We find that the aerosol are very absorbing in nature, that is, they are warming the atmosphere, and that the absorbing/imaginary part of the refractive index is in the higher range of previously reported values. The aerosol at the site are dominated by emissions from fossil fuel and biomass burning sources. On comparing these absorbing properties with those simulated by climate models, we find that the climate models are not able to simulate the absorbing nature of these aerosol well. Hence, there is a need for more such measurements of the aerosol refractive index to improve climate models and ultimately improve our understanding of the effect of aerosol on our climate. Key Points: Estimate the aerosol effective refractive index (RI); imaginary RI ranges 0.076–0.145, higher than previously reported valuesA single scatter albedo of 0.7 reveals strongly absorbing components, with brown carbon absorption of 34–88 Mm−1Imaginary RI correlates well with near‐UV absorption by brown carbon, which has low volatility and is likely emitted from combustion sources [ABSTRACT FROM AUTHOR]

Published

2023

5. Monochromatic Wave of Fluid Pressure in a Porous Rock.

Author

Li, Guangquan, Miao, Yifang, and Mei, Yangming

Subjects

*WAVES (Fluid mechanics), *PHASE velocity, *GROUNDWATER flow, *COMPLEX numbers, *ROCK mechanics, *QUALITY factor

Abstract

From the perspective of rock mechanics, transmission of fluid pressure that drives groundwater flow is not instantaneous; instead it is a slow compressional (P) wave in porous rocks saturated with a fluid. In this paper, the approach of monochromatic wave is used to analyze the slow P‐wave. Permeability is derived as a function of the frequency of the wave. The permeability appears to be a complex number which asymptotes to Darcy permeability at the low frequency end but tends to vanish at the high frequency end. With Biot theory, the permeability predicts phase velocity and the quality factor of the monochromatic wave. Using Berea sandstone as an illustrative example, the complex‐number permeability can yield a lower phase velocity (within frequency of 105–108 Hz) and a larger attenuation (for frequency above 106 Hz) than Darcy permeability does. This study extends the recent research of the low‐frequency waves of fluid pressure to the regime of very high frequency. [ABSTRACT FROM AUTHOR]

Published

2023

6. Aggregated type handling in CoDiPack.

Author

Sagebaum, Max and Gauger, Nicolas R.

Subjects

AUTOMATIC differentiation, COMPLEX numbers, MATRIX multiplications, HANDLES, COMPLEX matrices

Abstract

The development of algorithmic differentiation (AD) tools focuses mostly on handling floating point types in the target language. Taping optimizations in these tools mostly focus on specific operations like matrix vector products. Aggregated types like std::complex are usually handled by specifying the AD type as a template argument. This approach provides exact results, but prevents the use of expression templates. If AD tools are extended and specialized such that aggregated types can be added to the expression framework, then this will result in reduced memory utilization and improve the timing for applications where aggregated types such as complex number or matrix vector operations are used. Such an integration requires a reformulation of the stored data per expression and a rework of the tape evaluation process. We will demonstrate the overheads on a synthetic benchmark and show the improvement when aggregated types are handled properly by the expression framework of the AD tool. [ABSTRACT FROM AUTHOR]

Published

2023

7. Resolution of singularities via deep complex‐valued neural networks.

Author

Nitta, Tohru

Subjects

*MATHEMATICAL singularities, *ARTIFICIAL neural networks, *MACHINE learning, *CRITICAL point (Thermodynamics), *ERROR functions

Abstract

It has been reported that training deep neural networks is more difficult than training shallow neural networks. Hinton et al. proposed deep belief networks with a learning algorithm that trains one layer at a time. A much better generalization can be achieved when pre‐training each layer with an unsupervised learning algorithm. Since then, deep neural networks have been extensively studied. On the other hand, it has been revealed that singular points affect the training dynamics of the learning models such as neural networks and cause a standstill of training. Naturally, training deep neural networks suffer singular points. As described in this paper, we present a deep neural network model that has fewer singular points than the usual one. First, we demonstrate that some singular points in the deep real‐valued neural network, which is equivalent to a deep complex‐valued neural network, have been resolved as its inherent property. Such deep neural networks are less likely to become trapped in local minima or plateaus caused by critical points. Results of experiments on the two spirals problem, which has an extreme nonlinearity, support our theory. Copyright © 2017 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2018

8. Dual-numbered Hopfield neural networks.

Author

Kobayashi, Masaki

Subjects

*ARTIFICIAL neural networks, *HOPFIELD network stability, *ALGEBRA, *GEOMETRIC analysis, *CLIFFORD algebras

Abstract

In recent years, Hopfield neural networks using Clifford algebra have been studied. Clifford algebra is also referred to as geometric algebra, and is useful to deal with geometric objects. There are three kinds of Clifford algebra with degree 2; complex, hyperbolic, and dual-numbered. Complex-valued Hopfield neural networks have been studied by many researchers. Several models of hyperbolic Hopfield neural networks have also been proposed. It has been difficult to construct dual-numbered Hopfield neural networks. In this work, we propose dual-numbered Hopfield neural networks by modification of hyperbolic Hopfield neural networks with the split activation function. The stability condition and Hebbian learning rule are also provided. © 2017 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc. [ABSTRACT FROM AUTHOR]

Published

2018

9. Viability analysis of Kordofan giraffe (Giraffa camelopardalis antiquorum) in a protected area in Cameroon.

Author

Colston, Kane P. J., Johnson, Caspian L., Nyugha, Denis, Mengamenya Goué, Achile, and Penny, Samuel G.

Subjects

*GIRAFFES, *PROTECTED areas, *POPULATION viability analysis, *BIOLOGICAL extinction, *CORRIDORS (Ecology), *HABITAT conservation

Abstract

Representing one of the last populations of an IUCN Critically Endangered subspecies, estimates suggest the Kordofan giraffe of Cameroon's Bénoué Complex number fewer than 300 individuals, threatened by poaching and habitat degradation. This study investigated the viability of Bénoué National Park's Kordofan giraffe and efficacy of available interventions through a population viability analysis using VORTEX. The relative impacts of anti‐poaching activity, population supplementation, habitat protection and vaccination were explored, alongside a sensitivity analysis investigating parameter uncertainty. The baseline model projects a 78.6% probability of extinction (PE) within 100 years. Poaching of just two individuals every 5 years results in a 98.1% PE, highlighting anti‐poaching activity as a vital intervention. Movement of a female‐biased group into the park proved effective, with supplementation of 24 females reducing the PE by over 35%, sustaining a raised population size above the baseline for over 60 years on average. Annual carrying capacity reduction of 2% year−1 for 20 years resulted in a 97.8% PE. Conversely, habitat restoration had little consequence unless combined with further interventions. These findings underscore the magnitude of the threat facing Bénoué National Park's Kordofan giraffe. Conservation management should prioritise strengthening existing anti‐poaching activity in conjunction with protecting wildlife corridors to aid dispersal. [ABSTRACT FROM AUTHOR]

Published

2023

10. The number of Dirac‐weighted eigenvalues of Sturm–Liouville equations with integrable potentials and an application to inverse problems.

Author

Chen, Xiao and Qi, Jiangang

Subjects

INVERSE problems, STURM-Liouville equation, ALGORITHMS, DIRICHLET problem, DIRAC function, EIGENVALUES

Abstract

In this paper, we further Meirong Zhang et al.'s work by computing the number of weighted eigenvalues for Sturm–Liouville equations, equipped with general integrable potentials and Dirac weights, under Dirichlet boundary condition. We show that, for a Sturm–Liouville equation with a general integrable potential, if its weight is a positive linear combination of n Dirac delta functions, then it has at most n (may be less than n, or even be 0) distinct real Dirichlet eigenvalues, or every complex number is a Dirichlet eigenvalue; in particular, under some sharp condition, the number of Dirichlet eigenvalues is exactly n. Our main method is to introduce the concepts of characteristics matrix and characteristics polynomial for Sturm–Liouville problem with Dirac weights and put forward a general and direct algorithm used for computing eigenvalues. As an application, a class of inverse Dirichlet problems for Sturm–Liouville equations involving single Dirac distribution weights is studied. [ABSTRACT FROM AUTHOR]

Published

2021

11. Identification of invalid time‐delay‐groups using discriminant and Jacobian‐determinant in acoustic emission PD source localisation.

Author

Antony, Deepthi and Punekar, Gururaj S.

Abstract

The key problem in locating a source of partial discharge (PD) using the acoustic emission technique is the error in estimating the signal arrival time from the source to the multiple sensors. When the time difference of arrival approach is used for the PD‐source‐localisation, some of the measured time‐delay‐groups will have solution for the time‐difference equation in the complex‐number‐field. This is due to the significant error in the arrival time estimation. Such time‐delay‐groups should be considered to be invalid. In this study, a function is proposed for identifying the invalid time‐delay‐groups for the fixed set of coordinates of four sensors and the specific velocity of the acoustic signal used. The negative sign of this function value indicates that the solution is in the complex‐number‐field. An alternative method for identifying the invalid time‐delay‐groups is by using Newton's method. The multiple sign changes of the Jacobian‐determinant in the iterations of Newton's method shows that the solution is in the complex‐number‐field. The proposed methods have been tested with data from the existing literature, and results have confirmed the efficacy of these methods in the identification of the invalid time‐delay‐groups. Discarding such groups of time delays improves the accuracy of statistical PD‐source‐localisation. [ABSTRACT FROM AUTHOR]

Published

2017

12. Semi‐tensor product of quaternion matrices and its application.

Author

Fan, Xueling, Li, Ying, Ding, Wenxv, and Zhao, Jianli

Subjects

*MATRIX multiplications, *IMAGE reconstruction, *TENSOR products, *TENSOR algebra, *QUATERNIONS

Abstract

Unlike real or complex numbers, quaternion multiplication does not satisfy the commutative law. This makes it impossible to generalize some conclusions on semi‐tensor product to quaternion directly, which is valid on real or complex number fields. In this paper, we define semi‐tensor product of quaternion matrices and study the properties of semi‐tensor product of quaternion matrices, and the conclusion is applied to the color digital image restoration model. [ABSTRACT FROM AUTHOR]

Published

2023

13. An efficient approach for whirling speeds and mode shapes of uniform and nonuniform Timoshenko shafts mounted by arbitrary rigid disks.

Author

Wu, Jong‐Shyong and Hsu, Tzu‐Fu

Abstract

In theory, the whirling motion of a shaft‐disk system is three‐dimensional (3D), however, if the transverse displacement in the vertical principal xy‐plane and that in the horizontal principal xz‐plane for the cross‐section of the shaft located at the axial coordinate x are represented by a complex number, then the mass moment of inertia for unit shaft length (at x) and that for each rigid disk i can be combined with their associated gyroscopic moments (GMs) to form the frequency‐dependent equivalent mass moments of inertia, respectively, in the equations of motion for the rotating Timoshenko shaft carrying arbitrary rigid disks. It is found that the above‐mentioned equations for the rotating 3D shaft‐disk system take the same forms as the corresponding ones for the associated stationary two‐dimensional (2D) Timoshenko beam carrying the same number of disks, so that the approaches for the free vibration analyses of the stationary 2D beam‐disk system can be used to solve the title problem for obtaining the whirling speeds and mode shapes of a rotating 3D shaft‐disk system. Since the order of the eigenproblem equation derived from the presented approach is much smaller than that derived from the conventional finite element method (FEM), the computer time consumed by the former is much less than that by the latter. In addition, the solutions obtained from the presented approach are exact and may be the benchmark for evaluating the accuracy of solutions of the other approximate methods. Numerical examples reveal that the presented approach is available for the uniform or nonuniform shaft‐disk system, and the obtained results are very close to those obtained from existing literature or the FEM. The formulation of this article is available for a shaft‐disk system with various boundary conditions (BCs), to save space, only the cases with pinned‐pinned BCs are illustrated. [ABSTRACT FROM AUTHOR]

Published

2020

14. Considerations and adaptions to the modulated arc total body irradiation technique: dosimetry description.

Author

Effeney, Beth, Biggs, Jennifer, Brady, Carole, Pemberton, Melanie, Sim, Lucy, and Pullar, Andrew

Subjects

TOTAL body irradiation, RADIATION dosimetry, COMPLEX numbers, PRODUCTION planning, PLANNING techniques

Abstract

Total body irradiation (TBI) is a complex treatment technique, which has been slow to transition to a three-dimensional (3D) planning approach. There is limited literature available providing a detailed description on methods to plan TBI on a 3D planning system. 3D planning using the modulated arc TBI (MATBI) technique is a complex process involving a significant number of quality assurance processes and scripts, due to more than 40 treatment beams and two patient positions. This article will focus on the workflow and technical planning aspects of our institution's MATBI technique and identify reasons for modifications made to the developing institution's original MATBI approach. Included is a description of specific simulation equipment, detailed explanation of the four-stage computing process including the role of scripting to standardise and streamline what is otherwise a complex number of steps. The information provided is specific to one centre's approach but shows the fundamental planning process and demonstrates a streamlined method, which can be adapted to other planning systems. Overall, the ability to accurately represent the TBI technique in 3D on a planning system will be shown. [ABSTRACT FROM AUTHOR]

Published

2019

15. Split‐type octonion matrix.

Author

Bektaş, Özcan

Subjects

CAYLEY numbers (Algebra), REAL numbers, COMPLEX numbers, COMPLEX matrices, QUATERNIONS, NONASSOCIATIVE algebras

Abstract

The split and hyperbolic (countercomplex) octonions are eight‐dimensional nonassociative algebras over the real numbers, which are in the form X=x0e0+∑j=17xjej, where em's 0≤m≤7 have different properties for them. The main purpose of this paper is to define the split‐type octonion and its matrix whose inputs are split‐type octonions and give some properties for them by using the real quaternions, split, and hyperbolic (countercomplex) octonions. On the other hand, to make some definitions, we present some operations on the split‐type octonions. Also, we show that every split‐type octonions can be represented by 2 × 2 real quaternion matrix and 4 × 4 complex number matrix. The information about the determinants of these matrix representations is also given. Besides, the main features of split‐type octonion matrix concept are given by using properties of  real quaternion matrices. Then, 8n × 8nreal matrix representations of split‐type octonion matrices are shown, and some algebraic structures are examined. Additionally, we introduce real quaternion adjoint matrices of split‐type octonion matrices. Moreover, necessary and sufficient conditions and definitions are given for split‐type octonion matrices to be special split‐type octonion matrices. We describe some special split‐type octonion matrices. Finally, oct‐determinant of split‐type octonion matrices is defined. Definitive and understandable examples of all definitions, theorems, and conclusions were given for a better understanding of all these concepts. [ABSTRACT FROM AUTHOR]

Published

2019

16. 2D Magnetotelluric Inversion Using Linear Finite Element Methods and a Discretize‐Last Strategy With First and Second–Order Anisotropic Regularization.

Author

Codd, Andrea, Gross, Lutz, and Kerr, Janelle

Abstract

We present a new inversion scheme for 2D magnetotelluric data. In contrast to established approaches, it is based on a mesh‐free formulation of the Quasi‐Newton Broyden–Fletcher–Goldfarb–Shanno (BFGS) iteration which uses the cost function gradient to implicitly construct approximations of the Hessian inverse to update the unknown conductivity. We introduce conventional first–order regularization as well as second–order regularization where inversions based on the latter are more appropriate for sparse data and can be read as maximum likelihood estimation of the unknown conductivity. We apply first–order finite element method (FEM) discretizations of the inversion scheme, forward and adjoint problems, where the latter is required for the construction of the cost function gradients. We allow for unstructured first–order triangular meshes supporting an enhanced ground level resolution including topographical features and coarsening at the far field leading to significant reduction in computational costs from using structured mesh. Formulating the inversion iteration in continuous form prior to discretization eliminates bias due to local refinements in the mesh and gives way for computationally efficient sparse matrix techniques in the implementation. A keystone in the new scheme is the multi‐grid approximation of the Hessian of the regularizations to construct efficient preconditioning for the inversion iteration. The method is applied to the Commeni4 benchmark and two field data sets. Tests show that for both first and second–order regularization an anisotropic approach is important to address the vast differences in horizontal and vertical spatial scale which in conventional approaches is implicitly introduced through the elongated shape of grid cells. Plain Language Summary: We have developed a new inversion scheme for 2D MT data. Like most inversion methods, the cost function is composed of data misfit and a measure of the smoothness of the model (regularization). Inversion solutions are found by taking the derivative of the cost function and setting it to zero to minimize the function. The minimizing equation is solved iteratively using a quasi‐Newton method. Different to most other approaches, our method uses a discretize last strategy. Only once the quasi‐Newton iteration is derived, will discretization occur using an irregular triangular finite element mesh. The mesh is fine at ground level, very fine near measurement stations and extremely coarse at the edges of the model leading to significant reductions in computational costs compared to regular mesh. An additional feature of our method is two different types of regularization, conventional first‐order regularization and second‐order regularization, both with spatial anisotropy. This leads to multiple inversion solutions showing the variation of allowable solutions. Testing on benchmark and field data shows our method's robustness and its potential for real‐world applications. Key Points: New 2D MT inversion with both first and second–order anisotropic regularization for resolving different spacial characteristicsThe discretize‐last‐strategy implements a mesh‐free, gradient based inversion schemeMulti‐resolution preconditioning with efficient sparse matrix techniques accelerates computations [ABSTRACT FROM AUTHOR]

Published

2024

17. Temperature Is Likely an Important Omission in Interpreting Vegetation Optical Depth.

Author

Zhao, Meng, Humphrey, Vincent, Feldman, Andrew F., and Konings, Alexandra G.

Subjects

PLANT biomass, COMPUTATIONAL electromagnetics, RESEARCH personnel, BIOMASS, AQUATIC plants

Abstract

Vegetation optical depth (VOD) satellite microwave retrievals provide significant insights into vegetation water content and responses to hydroclimatic changes. While VOD variations are commonly linked to dry biomass and live fuel moisture content (LFMC), the impact of canopy temperature (Tc) remains overlooked in large‐scale studies. Here, we investigated the impact of Tc on L‐band (1.4 GHz) and X‐band (10.7 GHz) VOD at diurnal and seasonal timescales. Synthetic benchmark VOD was created using realistic fields of Tc, LFMC, and biomass in an electromagnetic model. Perturbation experiments revealed that Tc strongly affects diurnal VOD variations at both L‐band and X‐band. Seasonally, while biomass emerges as the largest contributor to VOD variations in 70% (at X‐band) and 90% (at L‐band) of our study region, Tc and LFMC still play substantial roles. The findings stress the importance of refining retrieval algorithms to distinguish Tc, LFMC, and biomass effects for future VOD applications in ecohydrology. Plain Language Summary: Satellite measurements known as vegetation optical depth (VOD) are sensitive to how much water plants contain (i.e., their hydration level). Because of this, VOD allows researchers to study how ecosystems respond to changes in weather, climate, and other factors. However, besides water, other variables like the temperature of the plants and their biomass can also change satellite VOD readings. In this study, we used computer simulations to examine how canopy temperature, relative water content, and plant biomass may affect these satellite readings. We found that canopy temperature has a surprisingly strong impact on VOD variations, especially at the diurnal timescale. Our results highlight the need to account for plant temperature influence in future VOD applications. Key Points: A simulation approach was used to investigate how canopy temperature, live fuel moisture content, and dry biomass affect VOD variationsThe impact of canopy temperature on VOD variations is more substantial than previously assumed, both at diurnal and seasonal timescalesTo interpret VOD dynamics, algorithms should differentiate between temperature, live fuel moisture content, and biomass contributions [ABSTRACT FROM AUTHOR]

Published

2024

18. Vertically Resolved Analysis of the Madden‐Julian Oscillation Highlights the Role of Convective Transport of Moist Static Energy.

Author

Yang, Da, Yao, Lin, and Hannah, Walter

Subjects

ATMOSPHERIC boundary layer, THUNDERSTORMS, ATMOSPHERIC turbulence, CONVECTIVE clouds, BOUNDARY layer (Aerodynamics)

Abstract

We simulate the Madden‐Julian oscillation (MJO) over an aquaplanet with uniform surface temperature using the multiscale modeling framework (MMF) configuration of the Energy Exascale Earth System Model (E3SM‐MMF). The model produces MJO‐like features that have a similar spatial structure and propagation behavior to the observed MJO. To explore the processes involved in the propagation and maintenance of these MJO‐like features, we perform a vertically resolved moist static energy (MSE) analysis for the MJO (Yao et al., 2022, https://doi.org/10.1175/jas‐d‐20‐0254.1). Unlike the column‐integrated MSE analysis, our method emphasizes the local production of MSE variance and quantifies how individual physical processes amplify and propagate the MJO's characteristic vertical structure. We find that radiation, convection, and boundary layer (BL) processes all contribute to maintaining the MJO, balanced by the large‐scale MSE transport. Furthermore, large‐scale dynamics, convection, and BL processes all contribute to the propagation of the MJO, while radiation slows the propagation. Additionally, we perform mechanism‐denial experiments to examine the role of radiation and associated feedbacks in simulating the MJO. We find that the MJO can still self‐emerge and maintain its characteristic structures without radiative feedbacks. This study highlights the role of convective MSE transport in the MJO dynamics, which was overlooked in the column‐integrated MSE analysis. Plain Language Summary: We conduct simulations of the Madden‐Julian oscillation (MJO) using a computer model that can explicitly simulate deep convective clouds. The simulated MJO behaves similarly to what has been observed in the real world in terms of its spatial structure and propagation. We then delve into the detailed mechanisms behind the MJO, using a method that analyzes how energy and moisture move vertically through the atmosphere, rather than just averaging these properties across the whole atmosphere. This novel analysis shows that radiation, convection, turbulence in the atmospheric boundary layer, and large‐scale atmospheric flows all play roles in sustaining the MJO and affect its eastward propagation. Interestingly, the MJO can still develop and maintain its unique features without the influence of radiation, indicating other processes are also key. This research underscores the importance of understanding the vertical transport of energy and moisture by convective storms in studying the MJO, an aspect previously underappreciated in some simpler models and diagnoses. Key Points: We have successfully simulated the Madden‐Julian Oscillation (MJO) using the Energy Exascale Earth System Model‐multiscale modeling framework over an aquaplanet with uniform surface temperatureVertically resolved analyses of moist static energy highlight the role of convection in the maintenance and propagation of the MJOMechanism‐denial experiments show that radiative feedbacks are not essential to simulate the MJO [ABSTRACT FROM AUTHOR]

Published

2024

19. An analytical approach for power system frequency stability evaluation.

Author

Li, Zhenyao, Li, Jing, and Gan, Deqiang

Subjects

PERTURBATION theory, DYNAMIC stability, FREQUENCY stability, SYSTEMS theory, STABILITY theory

Abstract

Recent years have seen high penetration of renewable energies, which have significantly reduced the inertia of bulk power systems. As a result, the frequency behaviour of power systems is becoming more complex. To resolve this technical challenge, there is a particularly strong interest in developing analytical solutions for frequency dynamics studies. This study first describes a second‐order frequency dynamics model for power systems with renewable energies. A non‐linear perturbation approach is suggested to drive the analytical solution of the model. It is shown that, under many circumstances, frequency dynamics can be effectively approximated using a linear model. Subsequently, the article describes a fourth‐order linear frequency dynamics model that takes into account governor‐turbines. A polynomial eigenvalue method is proposed to identify the dominant and non‐dominant modes of the solution of the four‐order model. It is demonstrated that the dominant mode has a decisive impact on frequency behaviour, while the non‐dominant modes influence the relative frequency oscillations only. Finally, the study derives the analytical expressions of the standard frequency performance metrics and examines the impact of damping and inertia parameters. The introduced results are verified using two test systems, demonstrating the accuracy and effectiveness of the suggested method. [ABSTRACT FROM AUTHOR]

Published

2024

20. An analytical calculation method of SiC MOSFET junction temperature based on thermal network theory and Laplace transform.

Author

Wang, Lina, Qiu, Hongcheng, and Zhang, Liman

Subjects

LAPLACE transformation, ELECTRONIC systems, TEMPERATURE measurements, METAL oxide semiconductor field-effect transistors, SIMULATION methods & models

Abstract

In order for full utilization of the switching devices and safe continued operation of the power converter at the same time, the junction temperature of the switching devices needs to be accurately monitored without shutting down the motor drive. This paper derives an analytical junction temperature calculation method by using Laplace transformation and thermal network theory. Based on an actual motor drive, a simulation model is established using platform for power electronic systems (PLECS). Through comparison, the derived method is proven to be able to calculate junction temperature accurately. [ABSTRACT FROM AUTHOR]

Published

2024

21. Temporal Patterns of Angular Displacement of Endosomes: Insights into Motor Protein Exchange Dynamics.

Author

Jin, Siwoo, Ahn, Yongdeok, Park, Jiseong, Park, Minsoo, Lee, Sang‐Chul, Lee, Wonhee J., and Seo, Daeha

Subjects

BIOLOGICAL transport, ROTATIONAL motion, MOTOR ability, DYNEIN, NANOPARTICLES, MOLECULAR motor proteins

Abstract

The material transport system, facilitated by motor proteins, plays a vital role in maintaining a non‐equilibrium cellular state. However, understanding the temporal coordination of motor protein activity requires an advanced imaging technique capable of measuring 3D angular displacement in real‐time. In this study, a Fourier transform‐based plasmonic dark‐field microscope has been developed using anisotropic nanoparticles, enabling the prolonged and simultaneous observation of endosomal lateral and rotational motion. A sequence of discontinuous 3D angular displacements has been observed during the pause and run phases of transport. Notably, a serially correlated temporal pattern in the intermittent rotational events has been demonstrated during the tug‐of‐war mechanism, indicating Markovian switching between the exploitational and explorational modes of motor protein exchange prior to resuming movement. Alterations in transition frequency and the exploitation‐to‐exploration ratio upon dynein inhibitor treatment highlight the relationship between disrupted motor coordination and reduced endosomal transport efficiency. Collectively, these results suggest the importance of orchestrated temporal motor protein patterns for efficient cellular transport. [ABSTRACT FROM AUTHOR]

Published

2024

22. Control method based on real–imaginary decomposition at the switching frequency for multiple active bridge converters.

Author

Ibanez, Federico M., Shubnaya, Anna, and Martin, Fernando

Subjects

MULTIPORT networks, ELECTRIC vehicle charging stations, ELECTRICAL load, SIGNALS & signaling, SYMMETRY

Abstract

Isolated multiple port DC/DC converters, such as the Multiple Active Bridge (MAB) converter, have many recent applications, such as interconnection between grids, isolated uninterruptible power sources (UPSs) and electric vehicle chargers. MAB converter is an attractive solution from the point of view of the hardware because of its symmetry and its capability to be extended to any number of bridges with a moderate number of components. However, the main challenge of this converter is the control method in order to achieve independent control between the different ports and to minimize recirculating currents. For that reason, three‐port power converters have been already investigated, but many improvements can be done for a larger number of ports. This paper proposes to use a Fourier decomposition for the main power signals to separate their real and imaginary parts. As the signals work at the switching frequency, this decomposition is developed with analog electronics. Based on that, a general control method for regulating the power at the different ports is presented using the first harmonic component, which delivers most of the power. In this proposal, two nested control loops ensure accuracy for the DC power flow. Simulation and experimental results validate the proposal. [ABSTRACT FROM AUTHOR]

Published

2024

23. Optimising multi‐user wireless networks through discrete Fourier transform‐based channel estimation with cascaded intelligent reflecting surfaces.

Author

Monga, Sakhshra, Saluja, Nitin, Prabha, Chander, Garg, Roopali, Bairagi, Anupam Kumar, and Hassan, Md. Mehedi

Subjects

MEAN square algorithms, DISCRETE Fourier transforms, WIRELESS communications, TELECOMMUNICATION, LINEAR network coding, CHANNEL estimation

Abstract

Wireless communication systems are inherently challenged by factors such as fading, path loss, and shadowing, leading to potential errors in data transmission. Traditional methods to mitigate these issues include power control, diversification, variable beamforming, and modulation techniques. However, the unpredictable nature of the wireless medium often limits their effectiveness. A new approach to address these challenges is the implementation of cascaded intelligent reflecting surfaces (IRS). IRS systems consist of multiple passive elements that intelligently reflect electromagnetic waves, thereby enhancing signal quality. The Advanced Discrete Fourier Transform (ADFT) matrix scheme is explored in channel estimation, a novel method particularly suitable for wireless networks utilising cascaded IRS. The ADFT matrix scheme is significant for its efficiency in managing the common‐link configuration of cascading channel coefficients, which effectively reduces pilot overhead. When compared to traditional channel estimation methods like the Least Square|least squares, Maximal a posteriori probability, and Linear Minimum Mean Square Error, the ADFT matrix scheme exhibits superior performance. It achieves a remarkable reduction in normalised mean squared error (NMSE) – 66% and 80% at 20 dB and 15 dB Signal to‐Noise Ratios (SNR), respectively. Furthermore, increasing the pilot length correlates with enhanced NMSE performance, with a noted 33% improvement as the base station distance increases. Simulations demonstrate that with an escalation in the number of IRS elements and SNR, the ADFT matrix scheme consistently surpasses conventional methods. This advancement represents a significant leap in the field of wireless communication technology. [ABSTRACT FROM AUTHOR]

Published

2024

24. Relationship between blood coagulability and sense of burden among caregivers of patients with dementia.

Author

Hirano, Akemi, Suzuki, Yusuke, Umegaki, Hiroyuki, Hayashi, Toshio, Ina, Koichiro, Onishi, Joji, Hasegawa, Jun, and Kuzuya, Masafumi

Subjects

HEADACHE diagnosis, ANTIGENS, BLOOD coagulation factors, CHRONIC diseases, DEMENTIA patients, FIBRIN, INTERVIEWING, REGRESSION analysis, RISK assessment, SENILE dementia, SEX distribution, THROMBIN, TISSUE plasminogen activator, BODY mass index, VISUAL analog scale, BURDEN of care, CROSS-sectional method, FIBRIN fibrinogen degradation products

Abstract

Aim: This study aimed to examine the relationship between blood coagulability and sense of burden among caregivers of patients with senile dementia of the Alzheimer type. Methods: A cross‐sectional study was carried out involving healthy older caregivers who lived with their patients with senile dementia of the Alzheimer type. We evaluated the Zarit Burden Interview score, levels of von Willebrand factor antigen, D‐dimer, thrombin–antithrombin III complex, tissue plasminogen activator/plasminogen activator inhibitor type 1 complex, number of chronic diseases, body mass index and number of medications. A linear regression model was used to estimate adjusted associations. Results: Thrombin–antithrombin III complex levels were higher in female caregivers than in male caregivers (P = 0.07). Headaches were significantly more frequent in female caregivers than in male caregivers, as assessed by a visual analog scale (P < 0.01). The number of chronic diseases and body mass index were positively associated with levels of tissue plasminogen activator/plasminogen activator inhibitor type 1 complex (P < 0.05). Similarly, the number of medications was positively associated with levels of D‐dimer (P < 0.05). However, the Zarit Burden Interview score was not associated with blood coagulability (P > 0.05). Conclusions: The present study found that the number of chronic diseases and body mass index were associated with blood coagulability, and that female caregivers were more prone to headaches and higher blood coagulability than male caregivers. These findings highlight the essential nature of health management during caregiving. The impact of caregiver burden on blood coagulability is likely to differ depending on the long‐term or short‐term psychological stress associated with caregiving conditions. Geriatr Gerontol Int 2019; 19: 804–808. [ABSTRACT FROM AUTHOR]

Published

2019

25. Preventing pressure injuries in the emergency department: Current evidence and practice considerations.

Author

Santamaria, Nick, Creehan, Sue, Fletcher, Jacqui, Alves, Paulo, and Gefen, Amit

Subjects

PRESSURE ulcers, BIOMECHANICS, CRITICALLY ill, HOSPITAL emergency services, MEDICAL care costs, ORGANIZATIONAL effectiveness, PATIENTS, QUALITY assurance, EVIDENCE-based medicine, PREVENTION

Abstract

The emergency department (ED) is at the front line of hospital pressure injury (PI) prevention, yet ED clinicians must balance many competing clinical priorities in the care of seriously ill patients. This paper presents the current biomechanical and clinical evidence and management considerations to assist EDs to continue to develop and implement evidence‐based PI prevention protocols for the high‐risk emergency/trauma patient. The prevention of hospital‐acquired pressure injuries has received significant focus internationally over many years because of the additional burden that these injuries place on the patient, the additional costs and impact to the efficiency of the hospital, and the potential for litigation. The development of a PI is the result of a complex number of biomechanical, physiological, and environmental interactions. Our understanding of the interaction of these factors has improved significantly over the past 10 years. We have demonstrated that large reductions in PI incidence rates can be achieved in critical care and general hospital wards through the application of advanced evidence‐based prevention protocols and believe that further improvement can be achieved through the application of these approaches in the ED. [ABSTRACT FROM AUTHOR]

Published

2019

26. Square-root-extended complex Kalman filter for estimation of symmetrical components in power system.

Author

Cui, Bowen

Subjects

KALMAN filtering, ELECTRIC power, ELECTRIC potential, COMPLEX numbers, ACCURACY

Abstract

The paper presents a square-root-extended complex Kalman filter (SRECKF) by decomposing covariance matrix with its square-root forms to improve stability of the filter for estimating complex number. αβ transformation is used to map three-phase instantaneous voltages in the abc phases into instantaneous voltages on the αβ axes, and a non-linear state equation and observation equation of the three-phase voltages are built by introducing a complex vector and defining state variables. Positive symmetrical component, negative symmetrical components, and frequency of the three-phase voltages are estimated using traditional extended complex Kalman filter (ECKF), the estimation results show that the method proposed here are superior to traditional extended complex Kalman filter on estimation accuracy and convergence rate. [ABSTRACT FROM AUTHOR]

Published

2019

27. Efficient Computation of Green's Functions for Lossy Uniaxial Anisotropic Layered Media.

Author

Li, Dawei, Wilton, Donald R., Jackson, David R., Chen, Ji, and Wang, Hanming

Subjects

GREEN'S functions, ELECTROMAGNETIC waves, INTEGRAL equations, NUMERICAL analysis, ALGORITHMS

Abstract

The efficient computation of Green's functions for uniaxial anisotropic layered media is investigated. Both field and mixed‐potential layered medium Green's functions (LMGFs) are discussed for different applications. An asymptotic subtraction (singularity extraction) and the weighted average method are combined for the acceleration of LMGF computation. A full collection of Sommerfeld and related identities used in the acceleration is summarized and generalized to uniaxial anisotropic medium for both field and mixed‐potential LMGFs. When lossy media are considered, the effective distance from the source to the observation point becomes a complex number depending on the anisotropic ratio of the horizontal to vertical media parameters. In addition, the evaluation of half‐line source potentials, which are introduced to accelerate the scalar potential correction term for vertical currents, is generalized to the complex domain by analytic continuation. Several numerical examples are used to demonstrate the efficiency and accuracy of the resulting algorithms. Key Points: This paper computes Green's functions efficiently in lossy uniaxial anisotropic layered mediaA full collection of Sommerfeld and related identities is summarized and generalized to lossy uniaxial anisotropic medium [ABSTRACT FROM AUTHOR]

Published

2019

28. The loss‐bet paradox: Actuaries, accountants, and other numerate people rate numerically inferior gambles as superior.

Author

Peters, Ellen, Fennema, M.G., and Tiede, Kevin E.

Subjects

LIKES & dislikes, INDIVIDUAL differences, INDIVIDUALITY, JUDGMENT (Psychology), MATHEMATICAL ability

Abstract

Psychologists have convincingly demonstrated that preferences are not always stable and, instead, are often "constructed" based on information available in the judgment or decision context. In 4 studies with experts (accountants and actuaries in Studies 1 and 2, respectively) and a diverse lay population (Studies 3 and 4), the evidence was consistent with the highly numerate being more likely than the less numerate to construct their preferences by rating a numerically inferior bet as superior (i.e., the bets effect). Thus, the effect generalizes beyond a college student sample, and preference construction differs by numeracy. Contrary to prior thinking about preference construction, however, high expertise and high ability (rather than low) consistently related to the paradoxical phenomenon. Results across studies including Study 3's experimental modifications of the task supported the hypothesized number comparison process (and not a lack of expertise with monetary outcomes and probabilities or numeracy‐related differences in attention to numbers) as the effect's underlying cause. The bets effect was not attenuated by Study 4's instructions to think about what would be purchased with bet winnings. Task results combined with free‐response coding supported the notion that highly numerate participants have a systematic and persistent inclination for doing simple and complex number operations that drive their judgments (even after controlling for nonnumeric intelligence). Implications for 3 types of dual‐process theories are discussed. The results were inconsistent with default‐interventionist theories, consistent or unclear with respect to fuzzy trace theory, and consistent with interactive theories. [ABSTRACT FROM AUTHOR]

Published

2019

29. Defining the role of NK cells during dengue virus infection.

Author

Mathew, Anuja

Subjects

KILLER cells, PHENOTYPES, T cell receptors, DENGUE viruses, IMMUNOGLOBULINS

Abstract

Summary: In recent years, our understanding of the complex number of signals that need to be integrated between a diverse number of receptors present on natural killer (NK) cells and ligands present on target cells has improved. Here, we review the progress made in identifying interactions between dengue viral peptides presented on HLA Class 1 molecules with inhibitory and activating killer‐like immunoglobulin receptors on NK cells, direct interactions of viral proteins with NK cell receptors, the involvement of dengue virus‐specific antibodies in mediating antibody‐dependent cell‐mediated cytotoxicity and the role of soluble factors in modulating NK cell responses. We discuss findings of NK cell activation early after natural dengue infection, and point to the role that NK cells may play in regulating both innate and adaptive immune responses, in the context of our new appreciation of interactions of dengue virus with specific NK cell receptors. With a number of flavivirus vaccine candidates in clinical trials, how NK cells respond to attenuated dengue virus and subunit protein vaccine candidates and shape adaptive immunity will need to be considered. [ABSTRACT FROM AUTHOR]

Published

2018

30. Approximating Planar Conformal Maps Using Regular Polygonal Meshes.

Author

Chen, Renjie and Gotsman, Craig

Subjects

CONFORMAL mapping, NUMERICAL grid generation (Numerical analysis), MESH networks, GEOMETRIC function theory, APPROXIMATION theory

Abstract

Continuous conformal maps are typically approximated numerically using a triangle mesh which discretizes the plane. Computing a conformal map subject to user-provided constraints then reduces to a sparse linear system, minimizing a quadratic 'conformal energy'. We address the more general case of non-triangular elements, and provide a complete analysis of the case where the plane is discretized using a mesh of regular polygons, e.g. equilateral triangles, squares and hexagons, whose interiors are mapped using barycentric coordinate functions. We demonstrate experimentally that faster convergence to continuous conformal maps may be obtained this way. We provide a formulation of the problem and its solution using complex number algebra, significantly simplifying the notation. We examine a number of common barycentric coordinate functions and demonstrate that superior approximation to harmonic coordinates of a polygon are achieved by the Moving Least Squares coordinates. We also provide a simple iterative algorithm to invert barycentric maps of regular polygon meshes, allowing to apply them in practical applications, e.g. for texture mapping. [ABSTRACT FROM AUTHOR]

Published

2017

31. Improved input‐to‐state stability criteria for time‐varying switched singular systems.

Author

Lu, Junjie, Li, Yongqi, Wang, Shijie, and She, Zhikun

Subjects

STABILITY criterion, LYAPUNOV functions, TIME-varying systems

Abstract

This paper is dedicated to proposing improved input‐to‐state stability (ISS) criteria for a class of continuous‐time time‐varying switched singular systems (CTSSS) under slow/fast/slow‐fast switching signals. Specifically, for a CTSSS with time‐varying singular matrices, the authors start with an improved sufficient condition for verifying its ISS under slow switching signals based on the average dwell time method and a relaxed multiple Lyapunov function. Then, considering several or all subsystems may destroy the overall ISS, relaxed sufficient conditions are presented to ensure the ISS of the CTSSS under fast switching signals and slow‐fast switching signals, respectively. Note that the improvement of the proposed ISS criteria is embodied in the derivative of the required multiple Lyapunov functions along with the state trajectories of CTSSS can be positive or negative. Finally, three numerical examples are provided to illustrate the feasibility of the obtained results. [ABSTRACT FROM AUTHOR]

Published

2024

32. Phase response constrained symbol‐level waveform design for dual‐functional radar‐communication systems.

Author

Zhang, Tingxiao, Zhao, Yongbo, and Liu, Donghe

Subjects

RADAR signal processing, MIMO radar, BLOCK designs, QUALITY of service, DEGREES of freedom, MOBILE communication systems, RADAR

Abstract

In this letter, a novel algorithm is proposed to design symbol‐level waveform for dual‐functional radar‐communication (DFRC) systems with low range sidelobe. Different from current schemes design waveform at the block level, a phase response constraint is introduced at the symbol level to provide an additional degree of freedom to decrease the range sidelobe in the pulse compression procedure, which is highly desired in radar systems. In particular, the phase response at the target direction is constrained to be similar to the given reference phase, and the matching error between the designed beampattern and the desired one is minimized subject to the constant modulus constraint. Furthermore, to guarantee the quality of service for communication, constructive interference is exploited at the symbol level for each communication user. An alternating direction method of multipliers algorithm is also proposed to solve the resulting nonconvex optimization problem with tractable subproblems solved sufficiently by the manifold optimization and standard quadratic problem. Numerical simulation results demonstrate the performance of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

33. NetHD: Neurally Inspired Integration of Communication and Learning in Hyperspace.

Author

Poduval, Prathyush P., Ni, Yang, Zou, Zhuowen, Ni, Kai, and Imani, Mohsen

Abstract

The 6G network, the next‐generation communication system, is envisaged to provide unprecedented experience through hyperconnectivity involving everything. The communication should hold artificial intelligence‐centric network infrastructures as interconnecting a swarm of machines. However, existing network systems use orthogonal modulation and costly error correction code; they are very sensitive to noise and rely on many processing layers. These schemes impose significant overhead on low‐power internet of things devices connected to noisy networks. Herein, a hyperdimensional network‐based system, called NetHD$N e t H D$, is proposed, which enables robust and efficient data communication/learning. NetHD$N e t H D$ exploits a redundant and holographic representation of hyperdimensional computing (HDC) to design highly robust data modulation, enabling two functionalities on transmitted data: 1) an iterative decoding method that translates the vector back to the original data without error correction mechanisms, or 2) a native hyperdimensional learning technique on transmitted data with no need for costly data decoding. A hardware accelerator that supports both data decoding and hyperdimensional learning using a unified accelerator is also developed. The evaluation shows that NetHD$N e t H D$ provides a bit error rate comparable to that of state‐of‐the‐art modulation schemes while achieving 9.4 ×$\times$ faster and 27.8 ×$\times$ higher energy efficiency compared to state‐of‐the‐art deep learning systems. [ABSTRACT FROM AUTHOR]

Published

2024

34. Computing the stress intensity factor range for fatigue crack growth testing at 20 kHz.

Author

Sadek, Mohamed, Bergström, Jens, and Hallbäck, Nils

Subjects

FATIGUE crack growth, MODAL analysis, RAYLEIGH model, TRANSIENT analysis, HIGH cycle fatigue

Abstract

Inertia and damping influence the values of the stress intensity factors (SIFs) at high‐frequency loading and they must be included in computations. In the present study, different dynamic simulation procedures were carried out for two types of specimen geometries and the achieved SIF values were compared. Fast computation procedures such as harmonic modal analysis and direct steady‐state analysis were compared to the computationally expensive transient dynamic analysis. Two different methods for calculating the SIF, the J‐integral and the crack tip opening displacement (CTOD) methods, were applied and compared and the results showed a near perfect agreement in calculation of the mode I SIF. The Rayleigh damping model was introduced into the dynamic computation to investigate its effect and the results revealed a clear effect on the SIF at 20 kHz frequency. The fast direct steady‐state analysis showed good agreement to both harmonic modal and transient analysis with the different damping values used and is, after this study, the recommended procedure. [ABSTRACT FROM AUTHOR]

Published

2024

35. Modeling and adaptive control strategy of hybrid microgrid based on virtual synchronous generator.

Author

Wang, Jianfeng, Ramli, Nurulazlina, and Aziz, Noor Hafizah Abdul

Subjects

ADAPTIVE control systems, MICROGRIDS, ELECTRIC power distribution, SYNCHRONOUS generators, FUZZY logic

Abstract

Aiming at large system operation fluctuations caused by the technical control of virtual synchronous generators, this article studies the introduction of interface converter control power, builds a virtual synchronous generator (VSG)‐based hybrid microgrid model and adaptive control strategy. Finally it optimizes it with fuzzy logic to obtain an fuzzy logic controller (FLC) based adaptive VSG control strategy. The experimental results show that under the FLC‐based adaptive VSG control strategy, in the reverse current mode, the system regression time is 0.37 s, and the DC bus voltage is 6.5 V; In the rectification mode, the system regression time is 0.49 s, and the DC bus voltage is 2.1 V. The results obtained are faster than the traditional VSG control strategy, and the DC bus voltage is 42.48%–68.66% lower. In summary, the suggested control approach is effective and reliable under the two operation modes, which can make the system operate safely and stably. [ABSTRACT FROM AUTHOR]

Published

2024

36. Optimal control method of induction motor torque ripple based on harmonic component.

Author

Hu, Yinquan and Liu, Heping

Subjects

TORQUE, HARMONIC analysis (Music theory), INDUCTION motors, STATORS, ELECTRIC motors

Abstract

The torque ripple of an induction motor has strong harmonic interference, which causes stator current distortion. Stability control is always a difficult problem in this field. An optimal control method for the torque ripple of induction motors based on harmonic components is proposed. To address the instability and significant energy loss caused by torque ripple in induction motors, an optimization control method for torque ripple in induction motors based on harmonic components is studied and designed. On the basis of the induction motor model, according to the characteristics and generation principle of torque ripple, combined with controllable and uncontrollable parts of harmonic torque, the stator current harmonics are used to suppress torque harmonics and minimize torque ripple. For the purpose of to cancel the harmonic component of the output voltage, achieve digital output voltage filtering, reduce the harmonic component of the stator current, and achieve optimal control of the torque ripple of the induction motor, the resonant digital filter is simultaneously deployed at the controller's output. The test results showed that the maximum torque ripple value was 2 Nm and the minimum torque ripple value was 0.1 Nm, which can restrain the distortion of stator current to the greatest extent and reduce the harmonic content of torque. In summary, the optimization control method proposed in the study can effectively suppress harmonic interference, which has important practical implications for future harmonic research. [ABSTRACT FROM AUTHOR]

Published

2024

37. EEG functional connectivity as a Riemannian mediator: An application to malnutrition and cognition.

Author

Lopez Naranjo, Carlos, Razzaq, Fuleah Abdul, Li, Min, Wang, Ying, Bosch‐Bayard, Jorge F., Lindquist, Martin A., Gonzalez Mitjans, Anisleidy, Garcia, Ronaldo, Rabinowitz, Arielle G., Anderson, Simon G., Chiarenza, Giuseppe A., Calzada‐Reyes, Ana, Virues‐Alba, Trinidad, Galler, Janina R., Minati, Ludovico, Bringas Vega, Maria L., and Valdes‐Sosa, Pedro A.

Subjects

FUNCTIONAL connectivity, ELECTROENCEPHALOGRAPHY, MATRICES (Mathematics), RIEMANNIAN manifolds, MALNUTRITION

Abstract

Mediation analysis assesses whether an exposure directly produces changes in cognitive behavior or is influenced by intermediate "mediators". Electroencephalographic (EEG) spectral measurements have been previously used as effective mediators representing diverse aspects of brain function. However, it has been necessary to collapse EEG measures onto a single scalar using standard mediation methods. In this article, we overcome this limitation and examine EEG frequency‐resolved functional connectivity measures as a mediator using the full EEG cross‐spectral tensor (CST). Since CST samples do not exist in Euclidean space but in the Riemannian manifold of positive‐definite tensors, we transform the problem, allowing for the use of classic multivariate statistics. Toward this end, we map the data from the original manifold space to the Euclidean tangent space, eliminating redundant information to conform to a "compressed CST." The resulting object is a matrix with rows corresponding to frequencies and columns to cross spectra between channels. We have developed a novel matrix mediation approach that leverages a nuclear norm regularization to determine the matrix‐valued regression parameters. Furthermore, we introduced a global test for the overall CST mediation and a test to determine specific channels and frequencies driving the mediation. We validated the method through simulations and applied it to our well‐studied 50+‐year Barbados Nutrition Study dataset by comparing EEGs collected in school‐age children (5–11 years) who were malnourished in the first year of life with those of healthy classmate controls. We hypothesized that the CST mediates the effect of malnutrition on cognitive performance. We can now explicitly pinpoint the frequencies (delta, theta, alpha, and beta bands) and regions (frontal, central, and occipital) in which functional connectivity was altered in previously malnourished children, an improvement to prior studies. Understanding the specific networks impacted by a history of postnatal malnutrition could pave the way for developing more targeted and personalized therapeutic interventions. Our methods offer a versatile framework applicable to mediation studies encompassing matrix and Hermitian 3D tensor mediators alongside scalar exposures and outcomes, facilitating comprehensive analyses across diverse research domains. [ABSTRACT FROM AUTHOR]

Published

2024

38. Acoustic Wave‐Induced Stroboscopic Optical Mechanotyping of Adherent Cells.

Author

Combriat, Thomas, Olsen, Petter Angell, Låstad, Silja Borring, Malthe‐Sørenssen, Anders, Krauss, Stefan, and Dysthe, Dag Kristian

Subjects

HOMODYNE detection, ACOUSTIC transducers, MODULUS of rigidity, CELLULAR mechanics, BIOPHYSICS, ULTRASONIC equipment

Abstract

In this study, a novel, high content technique using a cylindrical acoustic transducer, stroboscopic fast imaging, and homodyne detection to recover the mechanical properties (dynamic shear modulus) of living adherent cells at low ultrasonic frequencies is presented. By analyzing the micro‐oscillations of cells, whole populations are simultaneously mechanotyped with sub‐cellular resolution. The technique can be combined with standard fluorescence imaging allowing to further cross‐correlate biological and mechanical information. The potential of the technique is demonstrated by mechanotyping co‐cultures of different cell types with significantly different mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2024

39. Weighted Sum Secrecy Rate Optimization for Cooperative Double-IRS-Assisted Multiuser Network.

Author

Shaochuan Yang, Kaizhi Huang, Hehao Niu, Yi Wang, Zheng Chu, Gaojie Chen, and Zhen Li

Subjects

LAGRANGE multiplier, MULTIUSER computer systems, CONCAVE functions, POWER transmission, PROBLEM solving, BEAMFORMING, TRANSMISSION of sound

Abstract

In this paper, we present a double-intelligent reflecting surfaces (IRS)-assisted multiuser secure system where the inter-IRS channel is considered. In particular, we maximize the weighted sum secrecy rate of the system by jointly optimizing the beamforming vector for transmitted signal and artificial noise at the base station (BS) and the cooperative phase shifts of two IRSs, under the constraints of transmission power at the BS and the unit-modulus phase shift of IRSs. To tackle the nonconvexity of the optimization problem, we first convert the objective function to its concave lower bound by utilizing a novel successive convex approximation technique, then solve the transformed problem iteratively by applying an alternating optimization method. The Lagrange dual method, Karush–Kuhn–Tucker conditions, and alternating direction method of multipliers are applied to develop a low-complexity solution for each subproblem. Finally, simulation results are provided to verify the advantages of the cooperative double-IRS scheme in comparison with the benchmark schemes. [ABSTRACT FROM AUTHOR]

Published

2024

40. Interpolation of positive matrices by quantum‐inspired optimal control.

Author

Jiang, Chen, Pan, Yu, Yang, Yi, and Dong, Daoyi

Subjects

INTERPOLATION, DISTRIBUTION (Probability theory), QUANTUM states, QUANTUM theory, OPTIMAL control theory

Abstract

Interpolation of probability distributions can be formulated as an optimal transport problem. Positive matrix, which can be viewed as the generalization of probability distribution to higher dimension, is used in quantum theory to describe the state of a quantum system. Here, a quantum‐inspired method for the interpolation of positive matrices is proposed. Particularly, this method employs the quantum state purification of the positive matrices in an extended space. Since pure state controllability can be easily achieved using open‐loop coherent control, the continuous interpolation of positive matrices is given as a completely positive map induced by simulating the optimal control for pure state transfer. The quantum‐inspired interpolation is shape‐preserving with applications to tensor field processing. [ABSTRACT FROM AUTHOR]

Published

2024

41. Fault estimation for nonlinear uncertain time‐delay systems based on unknown input observer.

Author

Azarbani, Ataollah, Fakharian, Ahmad, and Menhaj, Mohammad Bagher

Subjects

UNCERTAIN systems, NONLINEAR estimation, LINEAR matrix inequalities, TIME delay systems, NONLINEAR dynamical systems, NONLINEAR systems, ADAPTIVE control systems

Abstract

In this paper, a novel nonlinear unknown input observer is proposed in order to fault estimation for nonlinear uncertain systems with time delays. By the estimation of the faults, the features are detected such as shape, size occurrence time etc. The time delay is considered a constant and known parameter in the states. The disturbances are investigated in the states and outputs and also, and sensor and actuator faults are considered. The stability of the closed‐loop system is guaranteed by Lyapunov–Krasovskii theory and some feasible Linear matrix inequalities (LMI). The proposed method is simulated on a continuous‐stirred tank reactor (CSTR) with uncertainties and time delay. Simulation results show the appropriate efficiency of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

42. ACOD1, rather than itaconate, facilitates p62‐mediated activation of Nrf2 in microglia post spinal cord contusion.

Author

Qian, Zhanyang, Xia, Mingjie, Zhao, Tianyu, Li, You, Li, Guangshen, Zhang, Yanan, Li, Haijun, and Yang, Lei

Subjects

SPINAL cord, NUCLEAR factor E2 related factor, MICROGLIA, OXIDATIVE stress, NEUROINFLAMMATION, SPINAL cord injuries

Abstract

Background: Spinal cord injury (SCI)‐induced neuroinflammation and oxidative stress (OS) are crucial events causing neurological dysfunction. Aconitate decarboxylase 1 (ACOD1) and its metabolite itaconate (Ita) inhibit inflammation and OS by promoting alkylation of Keap1 to induce Nrf2 expression; however, it is unclear whether there is another pathway regulating their effects in inflammation‐activated microglia after SCI. Methods: Adult male C57BL/6 ACOD1−/− mice and their wild‐type (WT) littermates were subjected to a moderate thoracic spinal cord contusion. The degree of neuroinflammation and OS in the injured spinal cord were assessed using qPCR, western blot, flow cytometry, immunofluorescence, and trans‐well assay. We then employed immunoprecipitation‐western blot, chromatin immunoprecipitation (ChIP)‐PCR, dual‐luciferase assay, and immunofluorescence‐confocal imaging to examine the molecular mechanisms of ACOD1. Finally, the locomotor function was evaluated with the Basso Mouse Scale and footprint assay. Results: Both in vitro and in vivo, microglia with transcriptional blockage of ACOD1 exhibited more severe levels of neuroinflammation and OS, in which the expression of p62/Keap1/Nrf2 was down‐regulated. Furthermore, silencing ACOD1 exacerbated neurological dysfunction in SCI mice. Administration of exogenous Ita or 4‐octyl itaconate reduced p62 phosphorylation. Besides, ACOD1 was capable of interacting with phosphorylated p62 to enhance Nrf2 activation, which in turn further promoted transcription of ACOD1. Conclusions: Here, we identified an unreported ACOD1‐p62‐Nrf2‐ACOD1 feedback loop exerting anti‐inflammatory and anti‐OS in inflammatory microglia, and demonstrated the neuroprotective role of ACOD1 after SCI, which was different from that of endogenous and exogenous Ita. The present study extends the functions of ACOD1 and uncovers marked property differences between endogenous and exogenous Ita. Key points: ACOD1 attenuated neuroinflammation and oxidative stress after spinal cord injury.ACOD1, not itaconate, interacted with p‐p62 to facilitate Nrf2 expression and nuclear translocation.Nrf2 was capable of promoting ACOD1 transcription in microglia. [ABSTRACT FROM AUTHOR]

Published

2024

43. Nonlinear impedance matching control for a submerged wave energy converter.

Author

Gonzalez‐Esculpi, Alejandro, Verde, Cristina, and Maya‐Ortiz, Paul

Subjects

IMPEDANCE matching, IMPEDANCE control, WAVE energy, MECHANICAL impedance, ENERGY conversion, OFFSHORE structures, SUBMERGED structures

Abstract

The impedance matching control, also known as approximate complex conjugate control (ACC), is one of the main strategies for improving the capture of energy by point absorber wave energy converters. Such a strategy shapes the mechanical impedance related to the floater dynamics via the control law. Since the traditional ACC is given by a linear control law, this work proposes a generalization denoted as nonlinear complex conjugate control (NCC) that considers the presence of nonlinear viscous damping in addition to the usual linear damping and stiffness. The energy maximization conditions for the proposed NCC are derived in the frequency domain through the describing function method. These conditions show that the ACC is a special case of the NCC when the total damping on the floater is approximated as a linear function of its velocity. From numerical simulations of a point absorber wave energy converters with nonlinear damping, which is based on the Archimedes wave swing prototype, it is shown that the NCC provides greater energy conversion than the ACC, as well as a robust performance in the presence of variations of the damping coefficient and the excitation force peak frequency. [ABSTRACT FROM AUTHOR]

Published

2024

44. Phase‐coded radar waveform design with quantum annealing.

Author

Presles, Timothé, Enderli, Cyrille, Burel, Gilles, and Baghious, El Houssaïn

Subjects

QUANTUM annealing, COMBINATORIAL optimization, RADAR, QUANTUM computing, QUANTUM computers, MIMO radar

Abstract

The Integrated Side Lobe Ratio (ISLR) problem the authors consider here consists in finding optimal sequences of phase shifts in order to minimise the mean squared cross‐correlation side lobes of a transmitted radar signal and a mismatched replica. Currently, ISLR does not seem to be easier than the general polynomial unconstrained binary problem, which is NP‐hard. In their work, the authors aim to take advantage of the scalability of quantum computing to find new optima, by solving the ISLR problem on a quantum annealer. This quantum device is designed to solve quadratic optimisation problems with binary variables (QUBO). After proposing suitable formulation for different instances of the ISLR, the authors discuss the performances and the scalability of their approach on the D‐Wave quantum computer. More broadly, their work enlightens the limits and potential of the adiabatic quantum computation for the solving of large instances of combinatorial optimisation problems. [ABSTRACT FROM AUTHOR]

Published

2024

45. Parity‐Time Symmetry in Magnetic Materials and Devices.

Author

Zhang, Zhitao, Xin, Chao, and Liu, Haoliang

Subjects

MAGNETIC materials, MAGNETIC devices, PHASE transitions, SYMMETRY, ENERGY dissipation, EIGENVALUES

Abstract

Non‐Hermitian Hamiltonians may still possess real eigenvalues in case of the existence of parity‐time (PT) symmetry. Exceptional points (EPs) occur at the phase transition from real to complex eigenvalues due to PT‐symmetry breaking in the parameter space. Magnonic devices use magnons to carry, transport, and process information, which have the advantages of low energy dissipation, wave‐based computing, and nonlinear data processing. The combination of PT‐symmetry and magnonics may lead to novel physics as well as unprecedented functional device applications. Recently, the research of PT‐symmetry in magnetism has developed rapidly. In this review, the theoretical predictions as well as experimental findings of PT‐symmetry in magnetism are summarized. First, a brief introduction to PT symmetry, EPs, and anti‐PT symmetry is presented. Second, the theoretical and experimental progress of magnonic PT symmetry are summarized. Third, the theoretical predictions of higher‐order EPs and anti‐PT symmetry in magnonic systems are given. Finally, the study concludes by discussing the future challenges and research prospects in magnonic PT‐symmetry, and proposals for experimental observations of magnonic higher‐order EPs and anti‐PT symmetry are suggested. [ABSTRACT FROM AUTHOR]

Published

2024

46. Monitoring long‐term vegetation dynamics over the Yangtze River Basin, China, using multi‐temporal remote sensing data.

Author

Fu, Jing, Liu, Jianxiong, Qin, Jianxin, Yang, Liguo, Zhang, Zhongbo, Deng, Yunyuan, Hu, Yong, and Su, Baoling

Subjects

VEGETATION dynamics, WATERSHEDS, VEGETATION monitoring, REMOTE sensing, NORMALIZED difference vegetation index, SOUTHERN oscillation

Abstract

Vegetation plays a crucial role in nature, with intricate interactions between it and the geographical environment. The Yangtze River Basin (YRB) refers to the third largest river basin globally and an essential ecological security barrier in China. Monitoring vegetation dynamics in the basin is of profound significance for addressing climate change, soil erosion, and biodiversity loss in the basin's ecosystems. Here, we investigate the spatiotemporal variations of vegetation at both the basin and land cover scales in the YRB from 2000 to 2020. We elucidate the determinants driving the changes and explore future normalized difference vegetation index (NDVI) trends. The results indicate that NDVI in the YRB increased at a rate of 0.0032 year−1 (p < 0.01) over the past 21 years, and it is anticipated to maintain an upward trend in the future. Regions in the upper and middle reaches of the YRB demonstrated higher NDVI, whereas regions in the headwater area and the lower reaches showed lower NDVI. Significant vegetation improvement was primarily concentrated in the central part of the basin, while noticeable vegetation degradation was observed in the eastern region. Temperature and wind speed were identified as the primary controlling factors affecting vegetation greenness. Global‐scale climate oscillations played a significant role in driving periodic variations in NDVI, with La Niña events tending to increase NDVI, while El Niño events hindered its rise. Land cover types were influenced by long‐term interactions between natural factors and human activities, although short‐term vegetation variations might be more affected by the latter. Our findings provide valuable insights into the mechanisms behind vegetation variability driven by multiple variables, and the strong vegetation carbon sink capacity advances the conservation and development of ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

47. An extended impedance‐based fault location algorithm in power distribution system with distributed generation using synchrophasors.

Author

Chandran, Sandhya, Gokaraju, Ramakrishna, and Narendra, Krish

Subjects

PHASOR measurement, DISTRIBUTED power generation, FAULT location (Engineering), RELIABILITY in engineering

Abstract

Accurately locating power distribution faults reduces the total outage duration and provides better system reliability. Fault location using the traditional impedance‐based method may be very challenging in an active distribution system. However, taking into consideration the ease of implementation and cost effectiveness, a novel impedance‐based method is proposed to locate the fault by using the highly accurate time‐synchronized voltage and current phasors obtained from distribution phasor measurement units. The synchrophasor measurements obtained from the substation and various feeder segments are used in a two‐step algorithm based on the apparent impedance calculation to locate the exact source of the event. The algorithm uses phasor estimates to first identify the faulted feeder sub‐region and later uses measurements from a remote end device to eliminate pseudo‐faulted points to obtain the actual fault location. The effectiveness of the proposed method is realized using IEEE 34 bus system. Based on different fault types simulated at various parts of the system, the algorithm accurately estimates fault location in the range of ±1% of the line length. The proposed method is effective in locating faults for any type of network and topologies, with as many or as few (minimum 2) phasor measurement units in the system. [ABSTRACT FROM AUTHOR]

Published

2024

48. Quantitative processing of broadband data as implemented in a scientific split‐beam echosounder.

Author

Andersen, Lars Nonboe, Chu, Dezhang, Handegard, Nils Olav, Heimvoll, Harald, Korneliussen, Rolf, Macaulay, Gavin J., Ona, Egil, Patel, Ruben, and Pedersen, Geir

Subjects

ELECTRONIC data processing, FISHERIES, POPULATION ecology, BIOTIC communities, BACKSCATTERING, PIPELINE inspection

Abstract

The use of quantitative broadband echosounders for biological studies and surveys can offer considerable advantages over narrowband echosounders. These include improved spectral‐based target identification and significantly increased ability to resolve individual targets. An understanding of current processing steps is required to fully utilise and further develop broadband acoustic methods in marine ecology.We describe the steps involved in processing broadband acoustic data from raw data to frequency dependent target strength (TSf) and volume backscattering strength (Svf) using data from the EK80 broadband scientific echosounder as examples. Although the overall processing steps are described and build on established methods from the literature, multiple choices need to be made during implementation.To highlight and discuss some of these choices and facilitate a common understanding within the community, we have also developed a Python code which will be made publicly available and open source. The code follows the steps using raw data from two single pings, showing the step‐by‐step processing from raw data to TSf and Svf.This code can serve as a reference for developing custom code or implementation in existing processing pipelines, as an educational tool and as a starting point for further development of broadband acoustic methods in fisheries acoustics. [ABSTRACT FROM AUTHOR]

Published

2024

49. Radar‐based human activity recognition using denoising techniques to enhance classification accuracy.

Author

Yu, Ran, Du, Yaxin, Li, Jipeng, Napolitano, Antonio, and Le Kernec, Julien

Subjects

HUMAN activity recognition, OLDER people, WEARABLE cameras, CLASSIFICATION, MULTISPECTRAL imaging

Abstract

Radar‐based human activity recognition is considered as a competitive solution for the elderly care health monitoring problem, compared to alternative techniques such as cameras and wearable devices. However, raw radar signals are often contaminated with noise, clutter, and other artifacts that significantly impact recognition performance, which highlights the importance of prepossessing techniques that enhance radar data quality and improve classification model accuracy. In this study, two different human activity classification models incorporated with pre‐processing techniques have been proposed. The authors introduce wavelet denoising methods into a cyclostationarity‐based classification model, resulting in a substantial improvement in classification accuracy. To address the limitations of conventional pre‐processing techniques, a deep neural network model called Double Phase Cascaded Denoising and Classification Network (DPDCNet) is proposed, which performs end‐to‐end signal‐level classification and achieves state‐of‐the‐art accuracy. The proposed models significantly reduce false detections and would enable robust activity monitoring for older individuals with radar signals, thereby bringing the system closer to a practical implementation for deployment. [ABSTRACT FROM AUTHOR]

Published

2024

50. 2D Near‐Surface Full‐Waveform Tomography Reveals Bedrock Controls on Critical Zone Architecture.

Author

Eppinger, B. J., Holbrook, W. S., Liu, Z., Flinchum, B. A., and Tromp, J.

Subjects

WEATHERING, BEDROCK, TOMOGRAPHY, EARTHQUAKE zones, SURFACE of the earth, IMAGING systems in seismology

Abstract

For decades, seismic imaging methods have been used to study the critical zone, Earth's thin, life‐supporting skin. The vast majority of critical zone seismic studies use traveltime tomography, which poorly resolves heterogeneity at many scales relevant to near‐surface processes, therefore limiting progress in critical zone science. Full‐waveform tomography can overcome this limitation by leveraging more seismic data and enhancing the resolution of geophysical imaging. In this study, we apply 2D full‐waveform tomography to match the phases of observed seismograms and elucidate previously undetected heterogeneity in the critical zone at a well‐studied catchment in the Laramie Range, Wyoming. In contrast to traveltime tomograms from the same data set, our results show variations in depth to bedrock ranging from 5 to 60 m over lateral scales of just tens of meters and image steep low‐velocity anomalies suggesting hydrologic pathways into the deep critical zone. Our results also show that areas with thick fractured bedrock layers correspond to zones of slightly lower velocities in the deep bedrock, while zones of high bedrock velocity correspond to sharp vertical transitions from bedrock to saprolite. By corroborating these findings with borehole imagery, we hypothesize that lateral changes in bedrock fracture density majorly impact critical zone architecture. Borehole data also show that our full‐waveform tomography results agree significantly better with velocity logs than previously published traveltime tomography models. Full‐waveform tomography thus appears unprecedentedly capable of imaging the spatially complex porosity structure crucial to critical zone hydrology and processes. Plain Language Summary: Weathering processes within Earth's shallow subsurface break down rock into porous, mineral‐rich materials from which biota can access water and garner nutrients. Therefore, knowledge about weathering helps scientists better understand how Earth supports terrestrial life. An effective way of studying weathering is seismic imaging, whereby listening at Earth's surface to how mechanical waves propagate, we can make pictures of what is below and observe weathering in action. The seismic imaging method typically used to study weathering is first arrival traveltime tomography, although other methods can create higher resolution images. We applied an advanced seismic imaging technique called full‐waveform tomography to sharpen our view of the subsurface. Our waveform tomography results imply that changes in bedrock fracture density over relatively small lateral distances have a significant effect on how weathering processes operate. When the fracture density in the bedrock is low, there is a sharp transition from highly weathered materials to unaltered bedrock below. When the fracture density is high, the transition is more diffuse, and there exists a thick layer of weathered bedrock. Additionally, we ground truth these interpretations with in situ observations made in boreholes. Hence, waveform tomography appears capable of revealing new insights into subsurface structure and weathering processes. Key Points: We perform 2D full‐waveform tomography on shallow seismic refraction data to study critical zone architecture in the Laramie Range, WyomingBorehole data confirm that the full‐waveform tomography result is more accurate than conventional traveltime tomographyThe full‐waveform tomography model reveals critical zone heterogeneity likely caused by lateral changes in bedrock properties [ABSTRACT FROM AUTHOR]

Published

2024