Design of hollow ZnFe 2 O 4 microspheres@graphene decorated with TiO 2 nanosheets as a high-performance low frequency absorber

Physics-Informed Neural Networks (PINN) are neural networks encoding the problem governing equations, such as Partial Differential Equations (PDE), as a part of the neural network. PINNs have emerged as a new essential tool to solve various challenging problems, including computing linear systems arising from PDEs, a task for which several traditional methods exist. In this work, we focus first on evaluating the potential of PINNs as linear solvers in the case of the Poisson equation, an omnipresent equation in scientific computing. We characterize PINN linear solvers in terms of accuracy and performance under different network configurations (depth, activation functions, input data set distribution). We highlight the critical role of transfer learning. Our results show that low-frequency components of the solution converge quickly as an effect of the F-principle. In contrast, an accurate solution of the high frequencies requires an exceedingly long time. To address this limitation, we propose integrating PINNs into traditional linear solvers. We show that this integration leads to the development of new solvers whose performance is on par with other high-performance solvers, such as PETSc conjugate gradient linear solvers, in terms of performance and accuracy. Overall, while the accuracy and computational performance are still a limiting factor for the direct use of PINN linear solvers, hybrid strategies combining old traditional linear solver approaches with new emerging deep-learning techniques are among the most promising methods for developing a new class of linear solvers.

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Dimensional tailoring of nitrogen-doped graphene for high performance supercapacitors

RSC Advances ◽

10.1039/c6ra07825g ◽

2016 ◽

Vol 6 (60) ◽

pp. 55577-55583 ◽

Cited By ~ 3

Author(s):

Seung Yong Lee ◽

Chang Hyuck Choi ◽

Min Wook Chung ◽

Jae Hoon Chung ◽

Seong Ihl Woo

Keyword(s):

High Performance ◽

Low Frequency ◽

Frequency Region ◽

Transfer Resistance ◽

One Dimensional ◽

Nitrogen Doped ◽

Efficient Charge ◽

Nitrogen Doped Graphene ◽

Doped Graphene ◽

Low Mass

In supercapacitors, one dimensional graphene ribbons which form net-like porous structure demonstrate low mass transfer resistance at low frequency region and a consequent efficient charge transferability.

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A new time coding approach for CTVEP-based brain-computer interface

Journal of Computational Methods in Sciences and Engineering ◽

10.3233/jcm-194091 ◽

2020 ◽

Vol 20 (3) ◽

pp. 743-757

Author(s):

Teng Ma ◽

Xuezhuan Zhao

Keyword(s):

Information Transfer ◽

High Performance ◽

Visual Stimulation ◽

Brain Computer Interface ◽

Low Frequency ◽

Computer Interface ◽

Binary Codes ◽

Frequency Change ◽

Time Coding ◽

New Time

The chromatic transient visual evoked potential (CTVEP)-based brain-computer interface (BCI) can provide safer and more comfortable stimuli than the traditional VEP-based BCIs due to its low frequency change and no luminance variation in the visual stimulation. However, it still generates relatively few codes that correspond to input commands to control the outside devices, which limits its application in the practical BCIs to some extent. Aiming to obtain more codes, we firstly proposes a new time coding technique to CTVEP-based BCI by utilizing a combination of two 4-bit binary codes to construct four 8-bit binary codes to increase the control commands to extend its application in practice. In the experiment, two time-encoded isoluminant chromatic stimuli are combined to serve as different commands for BCI control, and the results show that the high performance based on the new time coding approach with the average accuracy up to 90.28% and average information transfer rate up to 27.78 bits/min for BCI can be achieved. It turns out that the BCI system based on the proposed method is feasible, stable and efficient, which makes the method very suitable for the practical application of BCIs, such as military, entertainment and medical enterprise.

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A Novel Vector Control Strategy for a Six-Phase Induction Motor with Low Torque Ripples and Harmonic Currents

Energies ◽

10.3390/en12061102 ◽

2019 ◽

Vol 12 (6) ◽

pp. 1102 ◽

Cited By ~ 6

Author(s):

Hamidreza Heidari ◽

Anton Rassõlkin ◽

Toomas Vaimann ◽

Ants Kallaste ◽

Asghar Taheri ◽

...

Keyword(s):

Vector Control ◽

Induction Motor ◽

Control Strategy ◽

High Performance ◽

Direct Torque Control ◽

Low Frequency ◽

Torque Control ◽

Harmonic Currents ◽

Torque Ripples ◽

Vector Control Strategy

In this paper, a new vector control strategy is proposed to reduce torque ripples and harmonic currents represented in switching table-based direct torque control (ST-DTC) of a six-phase induction motor (6PIM). For this purpose, a new set of inputs is provided for the switching table (ST). These inputs are based on the decoupled current components in the synchronous reference frame. Indeed, using both field-oriented control (FOC) and direct torque control (DTC) concepts, precise inputs are applied to the ST in order to achieve better steady-state torque response. By applying the duty cycle control strategy, the loss subspace components are eliminated through a suitable selection of virtual voltage vectors. Each virtual voltage vector is based on a combination of a large and a medium vector to make the average volt-seconds in loss subspace near to zero. Therefore, the proposed strategy not only notably reduces the torque ripples, but also suppresses the low frequency current harmonics, simultaneously. Simulation and experimental results clarify the high performance of the proposed scheme.

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High-performance low-frequency bistable vibration energy harvesting plate with tip mass blocks

Energy ◽

10.1016/j.energy.2019.05.002 ◽

2019 ◽

Vol 180 ◽

pp. 737-750 ◽

Cited By ~ 7

Author(s):

Yi Li ◽

Shengxi Zhou ◽

Zhichun Yang ◽

Tong Guo ◽

Xutao Mei

Keyword(s):

Energy Harvesting ◽

High Performance ◽

Low Frequency ◽

Vibration Energy ◽

Vibration Energy Harvesting ◽

Tip Mass

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A DFT technique for low frequency delay fault testing in high performance digital circuits

Proceedings. International Test Conference ◽

10.1109/test.2002.1041870 ◽

2003 ◽

Cited By ~ 4

Author(s):

B. Chatterjee ◽

M. Sachdev ◽

A. Keshavarzi

Keyword(s):

High Performance ◽

Digital Circuits ◽

Low Frequency ◽

Fault Testing ◽

Delay Fault ◽

Delay Fault Testing

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Influence of Materials on the Performance Limits of Microactuators

MRS Proceedings ◽

10.1557/proc-1052-dd07-03 ◽

2007 ◽

Vol 1052 ◽

Author(s):

Prasanna Srinivasan ◽

S. Mark Spearing

Keyword(s):

Thin Films ◽

Shape Memory ◽

High Performance ◽

Low Frequency ◽

Beam Theory ◽

Performance Limits ◽

Low Frequencies ◽

Thermal Actuators ◽

Work Volume ◽

Selection Of

AbstractThe selection of actuators at the micro-scale requires an understanding of the performance limits of different actuation mechanisms governed by the optimal selection of materials. This paper presents the results of analyses for elastic bi-material actuators based on simple beam theory and lumped parameter thermal models. Comparisons are made among commonly employed actuation schemes (electro-thermal, piezoelectric and shape memory) at micro scales and promising candidate materials are identified. Polymeric films on Si subjected to electro-thermal heating are optimal candidates for high displacement, low frequency devices while ferroelectric thin films of Pb-based ceramics on Si/ DLC are optimal for high force, high frequency devices. The ability to achieve ∼10 kHz at scales < 100μm make electro-thermal actuators competitive with piezoelectric actuators considering the low work/volume obtained in piezoelectric actuation (∼ 10−8J.m−3.mV−2). Although shape memory alloy (SMA) actuators such as Ni-Ti on Si deliver larger work (∼ 1 J.m−3K−2) than electro-thermal actuators at relatively low frequencies (∼ 1 kHz), the critical scale associated with the cessation of the shape memory effect forms the bounding limit for the actuator design. The built-in compressive stress levels (∼ 1GPa) in thin films of Si and DLC could be exploited for realizing a high performance actuator by electro-thermal buckling.

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Parallel 3-D marine controlled-source electromagnetic modelling using high-order tetrahedral Nédélec elements

Geophysical Journal International ◽

10.1093/gji/ggz285 ◽

2019 ◽

Vol 219 (1) ◽

pp. 39-65

Author(s):

Octavio Castillo-Reyes ◽

Josep de la Puente ◽

Luis Emilio García-Castillo ◽

José María Cela

Keyword(s):

High Performance ◽

Computational Cost ◽

Low Frequency ◽

Computation Time ◽

Multiple Scale ◽

High Order ◽

Physical Parameters ◽

Adaptive Meshing ◽

Controlled Source ◽

High Order Schemes

SUMMARY We present a parallel and high-order Nédélec finite element solution for the marine controlled-source electromagnetic (CSEM) forward problem in 3-D media with isotropic conductivity. Our parallel Python code is implemented on unstructured tetrahedral meshes, which support multiple-scale structures and bathymetry for general marine 3-D CSEM modelling applications. Based on a primary/secondary field approach, we solve the diffusive form of Maxwell’s equations in the low-frequency domain. We investigate the accuracy and performance advantages of our new high-order algorithm against a low-order implementation proposed in our previous work. The numerical precision of our high-order method has been successfully verified by comparisons against previously published results that are relevant in terms of scale and geological properties. A convergence study confirms that high-order polynomials offer a better trade-off between accuracy and computation time. However, the optimum choice of the polynomial order depends on both the input model and the required accuracy as revealed by our tests. Also, we extend our adaptive-meshing strategy to high-order tetrahedral elements. Using adapted meshes to both physical parameters and high-order schemes, we are able to achieve a significant reduction in computational cost without sacrificing accuracy in the modelling. Furthermore, we demonstrate the excellent performance and quasi-linear scaling of our implementation in a state-of-the-art high-performance computing architecture.

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