Showing total 1,560 results

1. 卷烟用纸中助燃剂含量测定结果的不确定度评定.

Author

张英 and 吉玉岱

Subjects

CIGARETTES, MATHEMATICAL models, VOLUMETRIC analysis, COMBUSTION

Abstract

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

Published

2023

2. Commentary on Chapters 4 to 7: Students' Learning of Integer Addition and Subtraction Using Models

Author

Stacey, Kaye

Abstract

These four chapters describe studies of using models for integer addition and subtraction. The models draw principally on the two grounding metaphors of object collection and motion along a path. A strength of all chapters is detailed analysis of how the models are and can be implemented and how they influence student's learning. Together the chapters demonstrate that teaching with any model requires care and attention to achieve conceptual clarity. Teachers need to act entirely within in the world of the model, only later adding other models to round out the mathematical picture. The teaching of integers is a key point for maintaining students' confidence that mathematics is a subject that makes sense. These chapters demonstrate how use of models can assist in this goal. [For the complete volume, "Exploring the Integer Addition and Subtraction Landscape: Perspectives on Integer Thinking. Research in Mathematics Education," see ED612853.]

Published

2018

3. Recent Findings in Nonlinear Science and Numerical Simulation Described by Researchers from University of Sao Paulo (Paper the Local Behavior Around Switching Planes In a Mathematical Model To Chemoimmunotherapy).

Subjects

MODEL airplanes, COMPUTER simulation, MATHEMATICAL models, VECTOR fields, SCIENTIFIC communication

Abstract

Keywords: Ribeirao Preto; Brazil; South America; Nonlinear Science and Numerical Simulation; Drugs and Therapies; Health and Medicine; Mathematics; Therapy EN Ribeirao Preto Brazil South America Nonlinear Science and Numerical Simulation Drugs and Therapies Health and Medicine Mathematics Therapy 1316 1316 1 06/05/23 20230609 NES 230609 2023 JUN 9 (NewsRx) -- By a News Reporter-Staff News Editor at Immunotherapy Weekly -- Investigators discuss new findings in Mathematics - Nonlinear Science and Numerical Simulation. Ribeirao Preto, Brazil, South America, Nonlinear Science and Numerical Simulation, Drugs and Therapies, Health and Medicine, Mathematics, Therapy Keywords for this news article include: Ribeirao Preto, Brazil, South America, Nonlinear Science and Numerical Simulation, Drugs and Therapies, Health and Medicine, Mathematics, Therapy, University of Sao Paulo. [Extracted from the article]

Published

2023

4. SimCC: A novel method to consider both content and citations for computing similarity of scientific papers.

Author

Reyhani Hamedani, Masoud, Kim, Sang-Wook, and Kim, Dong-Jin

Subjects

*CITATION analysis, *COMPUTER systems, *HYBRID systems, *MATHEMATICAL models, *MEASURE theory

Abstract

To compute the similarity of scientific papers, text-based similarity measures, link-based similarity measures, and hybrid methods can be applied. The text-based and link-based similarity measures take into account only a single aspect of scientific papers, content or citations, respectively. The hybrid methods consider both content and citations; however, they do not carefully consider the relation between the content of a pair of papers involved in a citation relationship. In this paper, we propose a novel method, SimCC (similarity based on content and citations), that considers both aspects, content and citations, to compute the similarity of scientific papers. Unlike previous methods, SimCC effectively reflects both content and authority of scientific papers simultaneously in similarity computation by applying a new RA (relevance and authority) weighting scheme. Also, we propose an RA+R weighting scheme to consider the recency of papers and an RA+E weighting scheme to take into account the author expertise of papers in similarity computation. The effectiveness of our proposed method is demonstrated by extensive experiments on a real-world dataset of scientific papers. The results show that our method achieves more than 100% improvement in accuracy in comparison with previous methods. [ABSTRACT FROM AUTHOR]

Published

2016

5. Optimal design of a yoke-less axial flux switching PM motor based on multi-objective PSO.

Author

Rahmani Fard, Javad, Jamali Arand, Saadat, and Hemmati, Siroos

Subjects

PARTICLE swarm optimization, EVOLUTIONARY algorithms, PERMANENT magnet motors, MOTORS, PERMANENT magnets, ELECTRIC torque motors, MATHEMATICAL models

Abstract

Purpose: In this paper, an improved multiobjective particle swarm optimization (PSO) algorithm is proposed to optimize a three-phase, 12-slot, 19-pole, yokeless axial-field flux-switching permanent magnet (YASA-AFFSPM) motor. Design/methodology/approach: Based on the structural characteristics of the YASA-AFFSPM, a mathematical model is established to calculate the main size of the YASA-AFFSPM motor. The split ratio, stator axial length, sandwiching pole angle, rotor pole angle, PM arc and number of conductors per slot are selected as optimization variables. Also, the efficiency, power factor, cogging torque and average torque are considered as the optimization objectives. The objectives are optimized by combining the improved multiobjective PSO algorithm with electromagnetic calculation. Findings: Based on the proposed algorithm, the investigated motor is optimized. The on-load efficiency, power factor and average torque of the motor performance have increased by 0.87%, 3.13% and 10.39%, respectively. Moreover, the cogging torque and slot fill factor have undergone decreases of 8.57% and 3.34%, respectively. Finally, the effectiveness of the algorithm is verified using experiment results. Originality/value: So far, no comprehensive report has been observed on the optimization of the YASA-AFFSPM motor using evolutionary algorithms and the study of the effect of the motor parameters. Therefore, in this paper, the authors decided to investigate the effect of YASA-AFFSPM motor parameters and improve motor performance with the improved PSO method. [ABSTRACT FROM AUTHOR]

Published

2023

6. -种基于数学建模的烘缸轴承故障诊断方法.

Author

李志文

Subjects

FAULT diagnosis, JUDGMENT (Psychology), DIAGNOSIS methods, MATHEMATICAL models, ALARMS

Abstract

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

Published

2023

7. A TM-Based Adaptive Learning Data-Model for Trajectory Tracking and Real-Time Control of a Class of Nonlinear Systems.

Author

Li, Junkang, Fang, Yong, and Zhang, Liming

Subjects

REAL-time control, NONLINEAR systems, PROCESS control systems, TRACKING algorithms

Abstract

In this paper, a Takenaka-Malmquist (TM) basis function based equivalent data-model is established by an adaptive rational decomposition for the finite-time interval trajectory tracking control and real-time control of a class of nonlinear systems in the frequency domain. This data model can adaptively learn and match the control process of nonlinear systems. As a result, the proposed trajectory tracking as well as real-time control method can reflect the feature of adaptive learning in order-by-order decomposition, and the feasibility of the proposed method is guaranteed by the convergence of adaptive decomposition by TM basis function under the maximum selection principle (MSP) in Hardy space $H^{2}(\mathbb {D})$. Compared with the traditional model-free control method, this data learning model which matches the control process has obvious advantages in the system model expression and control accuracy. Simulation results at the end of this paper show the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2022

8. Paper examines early-stage blended learning models.

Author

Brown, Emily Ann

Subjects

EDUCATION associations, EDUCATION research, BLENDED learning, EDUCATION, LEARNING, MATHEMATICAL models

Abstract

The article discusses the report conducted by online education organization International Association for K-12 Online Learning (iNACOL) on the early-stage blended learning models for K-12 education. Highlighted are definitions of blended learning models including rotation model, flex model and enriched virtual model. The adoption of the personalized learning in blended learning environment is also explored.

Published

2015

9. Analysis and Implementation of Harmonic Injection Locking in Cross-Coupled Oscillators Exploiting Inter-Harmonic Translations.

Author

De Vroede, Ariane and Reynaert, Patrick

Subjects

HARMONIC analysis (Mathematics), DIPOLE antennas, SEMICONDUCTOR devices

Abstract

This paper proposes a new approach to above- $f_{max}$ power detection, using harmonic injection locking of a cross-coupled oscillator and the resulting change in oscillation amplitude. The paper starts with the development of a theoretical framework for this receiver. Two previous methodologies are combined: analyzing an injection-locked oscillator as an active device in a positive feedback loop with a frequency selective network; and the more recently proposed way of modeling non-linearities by using inter-harmonic translation coefficients. Using this framework, a compact equation for the expected voltage response of the receiver is derived. Finally, the design of a receiver consisting of a 200 GHz cross-coupled oscillator with a 600 GHz folded dipole antenna as its tank inductor is discussed. A Noise Equivalent Power (NEP) of 2.3 pW/ $\sqrt {\text {Hz}}$ is achieved with the proposed receiver. [ABSTRACT FROM AUTHOR]

Published

2022

10. Computer-Aided Systematic Topology Derivation of Single-Inductor Multi-Input Multi-Output Converters From Working Principle.

Author

Mo, Liping, Huang, Jiangming, Chen, Guipeng, Qing, Xinlin, and Hu, Yihua

Subjects

TOPOLOGY, GRAPH theory, MATRIX converters

Abstract

In this paper, aiming to systematically derive single-inductor multi-input multi-output (SI-MIMO) converters having favorable merits of high-density and low-cost, a basic model is firstly extracted from the working principle. Theoretically, by enumerating all possible connections of the basic model and one-by-one manually judging their effectiveness according to working criterions, multiple viable SI-MIMO topologies can be obtained, but with heavy workload. To simplify the topology derivation process, this paper also proposes a computer-aided method to replace the manual effort. By modelling the basic model and working criterions with graph theory, MATLAB codes can be developed to automatically screen out the effective topologies. With the proposed method, 8 three-port, 28 four-port and 115 five-port converters with single inductor are conveniently obtained, including both the existing and new topologies. Moreover, by configuring ports and switches in each derived topology, multiple specific converters can be further expanded. These converters can provide more options for practical engineering applications, and a new topology is also introduced and experimentally verified in the paper. [ABSTRACT FROM AUTHOR]

Published

2022

11. Control for Itô Stochastic Systems With Input Delay.

Author

Zhang, Huanshui and Xu, Juanjuan

Subjects

STOCHASTIC systems, CONTROL theory (Engineering), MATHEMATICAL models, COMMAND & control systems, INDUSTRIAL controls manufacturing, PROGRAMMABLE controllers

Abstract

This paper examines the long-standing problem of linear quadratic regulation and stabilization for Itô stochastic systems with input delay. This problem remains a primary challenge because the separation principle does not hold for Itô stochastic systems. This paper presents a complete solution to the problem: 1) The (sufficient and necessary) solvability condition of the optimal control and the analytical controller are given based on the modified Riccati differential equation defined herein. 2) The sufficient and necessary stabilization condition in mean square sense is explored. We show that the Itô stochastic system with input delay is stabilized if and only if the modified algebraic Riccati equation developed in this paper has a unique positive-definite solution. The essential obstacle encountered in this paper concerns a Delayed Forward-Backward Stochastic Differential Equation (D-FBSDE), which is mathematical challenging. [ABSTRACT FROM PUBLISHER]

Published

2017

12. THE 2017 HIMCM.

Author

SNOOK, KATHLEEN

Subjects

MATHEMATICS contests, MATHEMATICAL models, HIGH school students

Published

2018

13. Distributed Reinforcement Learning Containment Control for Multiple Nonholonomic Mobile Robots.

Author

Xiao, Wenbin, Zhou, Qi, Liu, Yang, Li, Hongyi, and Lu, Renquan

Subjects

REINFORCEMENT learning, MOBILE robots, DIFFERENTIAL games, ADAPTIVE fuzzy control, STABILITY theory, LYAPUNOV stability

Abstract

In this paper, the distributed optimal containment control problem for multiple nonholonomic mobile robots (NHMRs) differential game is studied via reinforcement learning. An approximation-based optimal control strategy is developed to ensure the optimal performance index and avoid the potential collision among agents. Firstly, the collision avoidance problem considered in this paper is addressed by exploiting a consensus-like interconnection on a directed graph and an error transformation function. Then, on the basis of the optimal backstepping technique, a single critic neural network is adopted to obtain the solution of the coupled Hamilton-Jacobi (HJ) equation, in which an improved learning mechanism is constructed to relax the requirement on initial control conditions. In addition, based on the Lyapunov stability theory, it is proved that all signals in the closed-loop optimal control are uniformly ultimately bounded. Finally, the proposed control protocol is applied to NHMRs system, which verifies that the solution of the coupled HJ equation solves the containment problem of differential game. [ABSTRACT FROM AUTHOR]

Published

2022

14. A new interval-valued fuzzy multi-objective approach for project time–cost–quality trade-off problem with activity crashing and overlapping under uncertainty.

Author

Mahdavi-Roshan, Pouyan and Mousavi, Seyed Meysam

Subjects

FUZZY sets, PROJECT managers, MATHEMATICAL models, SENSITIVITY analysis

Abstract

Purpose: Most projects are facing delays, and accelerating the pace of project progress is a necessity. Project managers are responsible for completing the project on time with minimum cost and with maximum quality. This study provides a trade-off between time, cost, and quality objectives to optimize project scheduling. Design/methodology/approach: The current paper presents a new resource-constrained multi-mode time–cost–quality trade-off project scheduling model with lags under finish-to-start relations. To be more realistic, crashing and overlapping techniques are utilized. To handle uncertainty, which is a source of project complexity, interval-valued fuzzy sets are adopted on several parameters. In addition, a new hybrid solution approach is developed to cope with interval-valued fuzzy mathematical model that is based on different alpha-levels and compensatory methods. To find the compatible solution among conflicting objectives, an arithmetical average method is provided as a compensatory approach. Findings: The interval-valued fuzzy sets approach proposed in this paper is denoted to be scalable, efficient, generalizable and practical in project environments. The results demonstrated that the crashing and overlapping techniques improve time–cost–quality trade-off project scheduling model. Also, interval-valued fuzzy sets can properly manage expressions of the uncertainty of projects which are realistic and practical. The proposed mathematical model is validated by solving a medium-sized dataset an adopted case study. In addition, with a sensitivity analysis approach, the solutions are compared and the model performance is confirmed. Originality/value: This paper introduces a new continuous-based, resource-constrained, and multi-mode model with crashing and overlapping techniques simultaneously. In addition, a new hybrid compensatory solution approach is extended based on different alpha-levels to handle interval-valued fuzzy multi-objective mathematical model of project scheduling with influential uncertain parameters. [ABSTRACT FROM AUTHOR]

Published

2023

15. Reconfigurable Filtering Power Divider With Arbitrary Operating Channels Based on External Quality Factor Control.

Author

Xu, Jin-Xu, Huang, Mo, Zhan, Wan-Li, and Zhang, Xiu Yin

Subjects

ELECTRIC power filters, QUALITY factor, POWER dividers, QUALITY control, PIN diodes, IMPEDANCE matching

Abstract

In this paper, we propose a scheme to design the reconfigurable filtering power divider with arbitrary operating channels based on external quality factor ($Q_{\mathbf {e}}$) control. By using an input feeding line, ${n}$ resonators, and $m$ output feeding lines, the $n^{\mathbf {th}}$ -order $m$ -way filtering power divider topology can be obtained with a simple configuration. A coupled-line output feeding structure loading with multiple PIN diodes is proposed to adjust the output $Q_{\mathbf {e}}$ values. Design theories for obtaining the desired $Q_{\mathbf {e}}$ values are provided. Then, the filtering power divider can be fully reconfigured in the states with one to $m$ operating channels. Good input matching can be achieved without using an additional reconfigurable impedance matching network in all these states, resulting in a size and loss reduction. For verification, a 2nd-order 4-way reconfigurable filtering power divider is designed, fabricated, and measured. As compared to the reported reconfigurable power dividers, the proposed design shows the merits of fully reconfigurable operating channels, favorable filtering responses, low insertion losses, high isolation, and a simple structure. [ABSTRACT FROM AUTHOR]

Published

2022

16. Relation Between INL and ACPR of RF DACs.

Author

Babamir, Seyed-Mehrdad and Razavi, Behzad

Subjects

COMPUTER architecture, DIGITAL-to-analog converters, TRANSMITTERS (Communication), INTEGRATED circuits, MATHEMATICAL models, RADIO frequency

Abstract

The integral nonlinearity of digital-to-analog converters manifests itself as adjacent-channel power in RF transmitters. This paper derives compact equations relating these two quantities and verifies the results by simulations. Both current-steering and switched-mode architectures are analyzed. [ABSTRACT FROM AUTHOR]

Published

2022

17. An Improved Predictive Current Control of Eight Switch Three-Level Post-Fault Inverter With Common Mode Voltage Reduction.

Author

Xiang, Chaoqun, Ouyang, Zekeng, Zhang, Xinan, Iu, Herbert Ho Ching, and Cheng, Shu

Subjects

VOLTAGE, ELECTRIC inverters, PROBLEM solving, PULSE width modulation transformers, TORQUE control, VOLTAGE control, TOPOLOGY

Abstract

Eight-switch three-phase post-fault inverter (ESTPI) is widely used as the reconfigured topology of three-phase three-level neutral point clamped DC/AC inverter when open-circuit fault occurs. A key technical challenge for the ESTPI is the post-fault controller design. The existing post-fault control approaches for the ESTPI suffer from the difficulty in trading off the current tracking performance, neutral point voltage (NPV) balancing and common mode voltage (CMV) levels. To solve this problem, this paper proposes an improved predictive current control algorithm. The proposed algorithm contributes to achieve accurate output current tracking while greatly reducing the CMV with a balanced NPV. Simulation and experimental results are presented to validate the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2022

18. Performance Analysis of an MLS-Based Interface for Impulse Response Estimation of Resistive and Capacitive Sensors.

Author

Radogna, Antonio Vincenzo, Capone, Simonetta, Francioso, Luca, Siciliano, Pietro Aleardo, and D'Amico, Stefano

Subjects

IMPULSE response, CAPACITIVE sensors, MEASUREMENT errors, ELECTROCHEMICAL analysis, IMPEDANCE spectroscopy, LENGTH measurement

Abstract

This paper presents a performance analysis of a system for electrochemical impedance spectroscopy (EIS). The system, composed by an analog front-end (AFE) and a custom microcontroller (MCU) board, performs the impulse response (IR) measurement of linear and time-invariant (LTI) systems with pseudo-random excitation signals. As a novelty, a specific AFE for the interfacing of two-terminal resistive and capacitive sensors is covered in detail. The paper proposes, for the first time, a mathematical model to predict the impact of the main noise sources in the measured IR. Thanks to the proposed approach, the AFE and the system’s parameters can be properly designed in order to reduce the error, thus, minimizing the energy-per-error figure of merit (FOM) as well. The AFE is realized as discrete-components circuit and it has been included in a custom MCU-based measurement system as an expansion module. The predicted results from the mathematical model, in terms of noise power, SNR, and measurement error are validated through system-level simulation and experimental measurements. The system performs the IR measurement with 1023 points, showing root-mean-square (RMS) measurement errors of 1% and 1.4% for the tested ADC sampling frequencies of 62.5 kHz and 125 kHz, respectively. These lead to excellent FOM values of 128.9 mJ $\cdot $ %2 and 252.6 mJ $\cdot $ %2 that outstand the state of the art. [ABSTRACT FROM AUTHOR]

Published

2022

19. Transfer Function Analysis of the Power Supply Rejection Ratio of Low-Dropout Regulators and the Feed-Forward Ripple Cancellation Scheme.

Author

Chen, Feng, Lu, Yasu, and Mok, Philip K. T.

Subjects

TRANSFER functions, POWER resources, TECHNOLOGY transfer, PHOTONIC band gap structures, SIMULATION software

Abstract

This paper presents a rigorous transfer function analysis of the power supply rejection ratio (PSRR) of low-dropout (LDO) regulators and the LDO with the feed-forward ripple cancellation (FFRC) scheme. Four main noise sources of conventional LDOs are first clarified. An efficient and accurate model is proposed to facilitate the analysis, and the transfer function, along with the poles and zeros, is derived based on the simplified model. Software simulation results and numerical plots are both demonstrated and compared to verify the analytical results, with respect to two specific design examples. The widely-used FFRC scheme for PSRR enhancement is also reinvestigated based on the proposed model. With the inclusion of the FFRC circuit, the new transfer function with new poles and zeros is presented. The working principles of the FFRC scheme are illustrated and the optimal FFRC case is clarified. The proposed model and the derived transfer function match well with the simulation results and the measurement results in prior works. The proposed model and the analytical results serve as the theoretical foundation of the design of high-PSRR LDOs. The recommended simulation methodology could be helpful during the circuit design phase. [ABSTRACT FROM AUTHOR]

Published

2022

20. Compensation Network Optimal Design Based on Evolutionary Algorithm for Inductive Power Transfer System.

Author

Chen, Weiming, Lu, Weiguo, Iu, Herbert Ho-Ching, and Fernando, Tyrone

Subjects

EVOLUTIONARY algorithms, CURRENT fluctuations, EVOLUTIONARY computation, ALGORITHMS, MATHEMATICAL models, EXPERIMENTAL design

Abstract

Conventional design and optimization of passive compensation network (PCN) for inductive power transfer (IPT) system are based on specific topologies. The demerits of this design method are: i) The topology is mostly chosen by experience; ii) The design parameters are not multi-objective optimal. Aiming at these issues, this paper proposes an optimal PCN design scheme based on evolutionary algorithm (EA) to synchronously optimize the topology and parameters of PCN for IPT system. Firstly, a unified mathematical model of the PCN is presented and derived by transmission matrix. Then, according to the mathematical model, the multi-objective functions (such as output fluctuation and efficiency) as well as the constraints (such as load and coupling coefficient) for the optimal PCN design are established. The EA based multi-objective optimal PCN design algorithm is further constructed. Six optimal results are obtained using the algorithm, and one optimized PCN having minimum output current fluctuation and high-efficiency is chosen to validate the effectiveness of the proposed design scheme in experiment. For the given IPT system with the optimized PCN, the maximum fluctuation of output current is no more than 11%, within 200% of load variation and about 77% of coupling variation. [ABSTRACT FROM AUTHOR]

Published

2020

21. PDE Based Adaptive Control of Flexible Riser System With Input Backlash and State Constraints.

Author

Tang, Li, Zhang, Xin-Yu, Liu, Yan-Jun, and Tong, Shaocheng

Subjects

RISER pipe, ADAPTIVE control systems, PARTIAL differential equations, LYAPUNOV functions, LYAPUNOV stability, STABILITY theory

Abstract

In this paper, a class of flexible riser systems modeled by partial differential equations (PDEs) with the backlash is considered. The backlash is formulated as the addition of a linear input and a interference-like term, then an new auxiliary item is introduced to compensate for the impact of this backlash. In addition, the constraint problem for the position and the velocity is also taken into consideration. To solve this constrain problem, the logarithmic barrier Lyapunov function is employed. For the flexible riser system, two kinds of adaptive controllers are proposed under the following two cases. One controller is designed when only the parameter of backlash is unknown. On the basis of this result, the other controller is presented when some system parameters cannot be measured through actual measurement. Then, combing the theory of Lyapunov stability, the two controllers can guarantee the boundedness of all signals in the closed-loop flexible riser system. Further, both the position and the velocity satisfy their corresponding constraint condition. Finally, the simulation example verifies that the proposed control method is effective. [ABSTRACT FROM AUTHOR]

Published

2022

22. Analyzing the Impact of Memristor Variability on Crossbar Implementation of Regression Algorithms With Smart Weight Update Pulsing Techniques.

Author

Afshari, Sahra, Musisi-Nkambwe, Mirembe, and Sanchez Esqueda, Ivan Sanchez

Subjects

ALGORITHMS, MEMRISTORS, COMPUTER architecture, MATHEMATICAL models, INTEGRATING circuits

Abstract

This paper presents an extensive study of linear and logistic regression algorithms implemented with 1T1R memristor crossbars arrays. Using a sophisticated simulation platform that wraps circuit-level simulations of 1T1R crossbars and physics-based models of RRAM (memristors), we elucidate the impact of device variability on algorithm accuracy, convergence rate and precision. Moreover, a smart pulsing strategy is proposed for practical implementation of synaptic weight updates that can accelerate training in real crossbar architectures. Stochastic multi-variable linear regression shows robustness to memristor variability in terms of prediction accuracy but reveals impact on convergence rate and precision. Similarly, the stochastic logistic regression crossbar implementation reveals immunity to memristor variability as determined by negligible effects on image classification accuracy but indicates an impact on training performance manifested as reduced convergence rate and degraded precision. [ABSTRACT FROM AUTHOR]

Published

2022

23. Wrinkled brain mimics paper ball.

Author

SANDERS, LAURA

Subjects

BRAIN anatomy, WRINKLE patterns, CEREBRAL cortex, MATHEMATICAL models

Abstract

The article looks at research by biologists Suzana Herculano-Houzel and Bruno Mota, reported in the journal "Science," on the mathematical relation between the extent of brain folding in different mammals and the cortex's thickness and surface area, parallel to that relationship in crumpled paper.

Published

2015

24. IEEE Transactions on Neural Networks information for authors.

Subjects

ARTIFICIAL neural networks, PERIODICALS, MACHINE learning, PUBLISHING, MATHEMATICAL models

Abstract

These instructions give guidelines for preparing papers for this publication. Presents information for authors publishing in this journal. [ABSTRACT FROM PUBLISHER]

Published

2016

25. Homeostatic Fault Tolerance in Spiking Neural Networks: A Dynamic Hardware Perspective.

Author

Johnson, Anju P., Liu, Junxiu, Millard, Alan G., Karim, Shvan, Tyrrell, Andy M., Harkin, Jim, Timmis, Jon, Mcdaid, Liam J., and Halliday, David M.

Subjects

FAULT tolerance (Engineering), ARTIFICIAL neural networks, HOMEOSTASIS, DIGITAL phase locked loops, FIELD programmable gate arrays, MATHEMATICAL models

Abstract

Fault tolerance is a remarkable feature of biological systems and their self-repair capability influence modern electronic systems. In this paper, we propose a novel plastic neural network model, which establishes homeostasis in a spiking neural network. Combined with this plasticity and the inspiration from inhibitory interneurons, we develop a fault-resilient robotic controller implemented on an FPGA establishing obstacle avoidance task. We demonstrate the proposed methodology on a spiking neural network implemented on Xilinx Artix-7 FPGA. The system is able to maintain stable firing (tolerance ±10%) with a loss of up to 75% of the original synaptic inputs to a neuron. Our repair mechanism has minimal hardware overhead with a tuning circuit (repair unit) which consumes only three slices/neuron for implementing a threshold voltage-based homeostatic fault-tolerant unit. The overall architecture has a minimal impact on power consumption and, therefore, supports scalable implementations. This paper opens a novel way of implementing the behavior of natural fault tolerant system in hardware establishing homeostatic self-repair behavior. [ABSTRACT FROM PUBLISHER]

Published

2018

26. Modeling entropy generation of magnetohydrodynamics flow of nanofluid in a porous medium: a review.

Author

Zahor, Feda Abdalla, Jain, Reema, Ali, Ahmada Omar, and Masanja, Verdiana Grace

Subjects

POROUS materials, NANOFLUIDS, MAGNETOHYDRODYNAMICS, ENTROPY, MATHEMATICAL models, HEAT transfer, FLOW velocity

Abstract

Purpose: The purpose of this paper is to review previous research studies on mathematical models for entropy generation in the magnetohydrodynamics (MHD) flow of nanofluids. In addition, the influence of various parameters on the velocity profiles, temperature profiles and entropy generation was studied. Furthermore, the numerical methods used to solve the model equations were summarized. The underlying purpose was to understand the research gap and develop a research agenda. Design/methodology/approach: This paper reviews 141 journal articles published between 2010 and 2022 on topics related to mathematical models used to assess the impacts of various parameters on the entropy generation, heat transfer and velocity of the MHD flow of nanofluids. Findings: This review clarifies the application of entropy generation mathematical models, identifies areas for future research and provides necessary information for future research in the development of efficient thermodynamic systems. It is hoped that this review paper can provide a basis for further research on the irreversibility of nanofluids flowing through different channels in the development of efficient thermodynamic systems. Originality/value: Entropy generation analysis and minimization constitute effective approaches for improving the performance of thermodynamic systems. A comprehensive review of the effects of various parameters on entropy generation was performed in this study. [ABSTRACT FROM AUTHOR]

Published

2023

27. A flexible mathematical model for crew pairing optimization to generate n-day pairings considering the risk of COVID-19: a real case study.

Author

Shafipour-Omrani, Bahareh, Rashidi Komijan, Alireza, Sadjadi, Seyed Jafar, Khalili-Damghani, Kaveh, and Ghezavati, Vahidreza

Subjects

COVID-19 pandemic, FUEL costs, MATHEMATICAL models, INTEGER programming, AIR travel, GENETIC algorithms

Abstract

Purpose: One of the main advantages of the proposed model is that it is flexible to generate n-day pairings simultaneously. It means that, despite previous researches, one-day to n-day pairings can be generated in a single model. The flexibility in generating parings causes that the proposed model leads to better solutions compared to existing models. Another advantage of the model is minimizing the risk of COVID-19 by limitation of daily flights as well as elapsed time minimization. As airports are among high risk places in COVID-19 pandemic, minimization of infection risk is considered in this model for the first time. Genetic algorithm is used as the solution approach, and its efficiency is compared to GAMS in small and medium-size problems. Design/methodology/approach: One of the most complex issues in airlines is crew scheduling problem which is divided into two subproblems: crew pairing problem (CPP) and crew rostering problem (CRP). Generating crew pairings is a tremendous and exhausting task as millions of pairings may be generated for an airline. Moreover, crew cost has the largest share in total cost of airlines after fuel cost. As a result, crew scheduling with the aim of cost minimization is one of the most important issues in airlines. In this paper, a new bi-objective mixed integer programming model is proposed to generate pairings in such a way that deadhead cost, crew cost and the risk of COVID-19 are minimized. Findings: The proposed model is applied for domestic flights of Iran Air airline. The results of the study indicate that genetic algorithm solutions have only 0.414 and 0.380 gap on average to optimum values of the first and the second objective functions, respectively. Due to the flexibility of the proposed model, it improves solutions resulted from existing models with fixed-duty pairings. Crew cost is decreased by 12.82, 24.72, 4.05 and 14.86% compared to one-duty to four-duty models. In detail, crew salary is improved by 12.85, 24.64, 4.07 and 14.91% and deadhead cost is decreased by 11.87, 26.98, 3.27, and 13.35% compared to one-duty to four-duty models, respectively. Originality/value: The authors confirm that it is an original paper, has not been published elsewhere and is not currently under consideration of any other journal. [ABSTRACT FROM AUTHOR]

Published

2022

28. A chaos study of fractal–fractional predator–prey model of mathematical ecology.

Author

Kumar, Ajay, Kumar, Sunil, Momani, Shaher, and Hadid, Samir

Subjects

*MATHEMATICAL models, *NONLINEAR functional analysis, *PREDATION, *LOTKA-Volterra equations, *BIFURCATION diagrams, *NONLINEAR systems, *ECOLOGICAL models, *DIFFERENTIAL equations

Abstract

This paper presents a mathematical model to examine the effects of the coexistence of predators on single prey. Based on fractal–fractional Atangana–Baleanu (AB) and Caputo operators, we present a newly developed system of differential equations for the predator–prey system. Our study utilized the fixed point postulate to investigate the uniqueness and existence of solutions. Additionally, Ulam's type of stability of the proposed model is established with the help of nonlinear functional analysis. Further bifurcation diagrams, as well as phase portraits, have been used to study the proposed system numerically and to analyze its behavior. The generalized non-linear system with fractal–fractional Atangana–Baleanu (AB) and Caputo non-integer operators have been solved numerically via the Toufik–Atangana (TA) scheme respectively. We have demonstrated the applicability and effectiveness of these methods by analyzing numerical simulations for the fractal–fractional predator–prey ecological model and the numerical simulation has been calculated by MATLAB programming. [ABSTRACT FROM AUTHOR]

Published

2024

29. The 2018 IM2C International Judges' Commentary.

Author

Stolwijk, Ruud

Subjects

MATHEMATICAL models, MATHEMATICS education

Published

2018

30. Financing a capital-constrained supply chain: factoring accounts receivable vs a BCT-SCF receivable chain.

Author

Tang, Dan and Zhuang, Xintian

Subjects

ACCOUNTS receivable, SUPPLY chains, TRANSSHIPMENT, INDUSTRIAL equipment, MATHEMATICAL models

Abstract

Purpose: Blockchain-driven supply chain finance (BCT-SCF) has recently been receiving increased global attention. A number of business programmes have been carried out using this approach, but existing research has rarely focussed on this novel SCF model. This paper aims to fill this gap by proposing a mathematical model to analyse the value of BCT-SCF. Design/methodology/approach: First, this paper considers a multi-period two-echelon supply chain consisting of a capital-constrained supplier and a newsvendor-like retailer. Then, two financing channels are proposed. The supply chain actors can either factor accounts receivable (AR) from a bank or obtain financing through a BCT-SCF platform by which AR can be converted into a bill receivable and used to make payment. Further, to investigate the preferences of all actors between the two financing channels, this paper compares the two channels and examines how the degree of financial constraints and the cost of implementing the BCT-SCF model impact the financing preferences of all actors. Findings: BCT-SCF model can help a supply chain realise its optimisation both in production and financing efficiency, the preference for the BCT-SCF model increases as the initial capital of supplier and the BCT-SCF platform usage fee rate decrease. Practical implications: This research bridges the gap between theoretical analysis of BCT-SCF and its realistic application. The results demonstrate that with the BCT-SCF model, a win-win situation among supply chain actors is possible, which is helpful for the supply chain to choose a more efficient financing channel. Originality/value: This research introduces a mathematical model based on the "receivable chain" of CZBank and the model is set in a multi-period supply chain, which is the first time BCT-SCF has been considered as part of a more complex but realistic background setting. [ABSTRACT FROM AUTHOR]

Published

2021

31. Research Paper Series.

Subjects

ECONOMIC policy, SCIENTIFIC method, MATHEMATICAL models

Published

2017

32. Stabilization for a General Class of Fractional-Order Systems: A Sampled-Data Control Method.

Author

Li, Xinyao, Wen, Changyun, Li, Xiaolei, and Deng, Chao

Subjects

DISCRETE-time systems, CLOSED loop systems, ADAPTIVE control systems, EXPONENTIATION

Abstract

In this paper, based on sampled-data control method, we address the stabilization problem for a general class of linear continuous-time fractional systems whose solution contains the Mittag-Leffler function that does not obey the basic exponentiation identity. By considering the infinite memory and hereditary characteristics of fractional-order calculus, we propose a sampled-data controller that guarantees the resulting closed-loop system to be asymptotically stable. Simulation examples are presented to demonstrate the effectiveness of the proposed controller and verify the established results. [ABSTRACT FROM AUTHOR]

Published

2022

33. A Model-Based Approach Digital Pre-Distortion Method for Current-Steering Digital-to-Analog Converters.

Author

Valet, Patrick, Schwingshackl, David, Gaier, Ulrich, and Tonello, Andrea M.

Subjects

DIGITAL-to-analog converters, TISSUE arrays, COMPUTER architecture, SIGNAL processing, CALIBRATION

Abstract

This paper presents a novel static digital pre-distortion (DPD) method for a current-steering digital-to-analog converter (CS-DAC). The proposed method utilizes the knowledge of the current cell array architecture to calculate the static mismatch currents of the cells. The mismatch values are stored in memory and added to the original input code to generate the new pre-distorted input word. The converter corrects the static error with its own current cells without incorporating an additional calibration DAC (CALDAC) or programmable current sources. This results in a reduction in area, power and simulation run times because of the simpler circuit design. An Overflow-Cell-Selection (OCS) is introduced as a novel solution to further enhance the static linearity of the converter. It also can be implemented as a software solution for already existing DAC designs which do not have an integrated DPD and lab/measurement equipment (e.g., arbitrary wave generator (AWG)). This poses as a strong differentiation factor compared to other state-of-the-art static DPD methods. The evaluation of the proposed DPD is done via simulations in MATLAB and on- chip measurements with a 14-bit CS-DAC in 16 nm. Single tone measurements show a performance gain of the total harmonic distortion (THD) of 12 dB. [ABSTRACT FROM AUTHOR]

Published

2022

34. Edge of Chaos Is Sine Qua Non for Turing Instability.

Author

Ascoli, Alon, Demirkol, Ahmet Samil, Tetzlaff, Ronald, and Chua, Leon

Subjects

BIOLOGICALLY inspired computing, MEMRISTORS, INTEGRATED circuits

Abstract

Diffusion-driven instabilities with pattern formation may occur in a network of identical, regularly-spaced, and resistively-coupled cells if and only if the uncoupled cell is poised on a locally-active and stable operating point in the Edge of Chaos domain. This manuscript presents the simplest ever-reported two-cell neural network, combining together only 7 two-terminal components, namely 2 batteries, 3 resistors, and 2 volatile NbOx memristive threshold switches from NaMLab, and subject to diffusion-driven instabilities with the concurrent emergence of Turing patterns. Very remarkably, this is the first time an homogeneous cellular medium, with no other dynamic element than 2 locally-active memristors, hence the attribute all-memristor coined to address it in this paper, is found to support complex phenomena. The destabilization of the homogeneous solution occurs in this second-order two-cell array if and only if the uncoupled cell circuit parameters are chosen from the Edge of Chaos domain. A deep circuit- and system-theoretic investigation, including linearization analysis and phase portrait investigation, provides a comprehensive picture for the local and global dynamics of the bio-inspired network, revealing how a theory-assisted approach may guide circuit design with inherently non-linear memristive devices. [ABSTRACT FROM AUTHOR]

Published

2022

35. Accurate Crosstalk Noise Modeling and Analysis of Non-Identical Lossy Interconnections Using Convex Optimization Method.

Author

Zahedi, Fatemeh, Mehrshahi, Esfandiar, and Jahanian, Ali

Subjects

INTEGRATED circuit interconnections, MULTICONDUCTOR transmission lines, ELECTRIC lines, SPEED, NOISE, INTEGRATED circuits

Abstract

Recent studies on integrated circuits interconnections are mainly concentrated on the analysis of crosstalk and delay, by taking the trade-off between accuracy, speed, and complexity into consideration. The new idea of this paper is to apply the convex optimization method to analyze crosstalk and delay of the lossy coupled interconnections in identical and non-identical forms. For this purpose, a simple and comprehensive model is proposed to cover the functional and dynamic crosstalk in a computationally-effective way. More specifically, various case studies are determined to analyze the transient response of the coupled transmission lines with arbitrary excitation sources in the presence of both capacitive and inductive coupling characteristics. To validate the model, the numerical and Advanced Design System (ADS) simulation results are compared to indicate the desired accuracy. The calculated crosstalk percentage error of the proposed model with respect to ADS and HSPICE are less than 1.03% and 1.19%, respectively. In addition, the computational speed of the proposed method is about twice higher than ADS and HSPICE. The proposed model is extendible to handle ${N}$ coupled lines, making it appropriate to model complex integrated circuit interconnections. [ABSTRACT FROM AUTHOR]

Published

2022

36. An Application Specific Vector Processor for Efficient Massive MIMO Processing.

Author

Attari, Mohammad, Ferreira, Lucas, Liu, Liang, and Malkowsky, Steffen

Subjects

PARALLEL processing, PROCESS capability, MIMO systems, TELECOMMUNICATION equipment, BASEBAND, MIMO radar

Abstract

This paper presents an implementation for a baseband massive multiple-input multiple-output (MIMO) application-specific instruction set processor (ASIP). The ASIP is geared with vector processing capabilities in the form of single instruction multiple data (SIMD), and furthermore exploits instruction level parallelism by employing a very large instruction word (VLIW) architecture. Additionally, a systolic array is built into the pipeline which is tuned to speed up matrix calculations. A parallel memory subsystem and stand-alone accelerators are integrated into the ASIP architecture in order to meet the processing requirement. The processor is synthesized in 22 nm FD-SOI technology running at a clock frequency of 800 MHz. The system achieves a maximum detection throughput of 0.75 Gb/s/mm2 for a $128\times 8$ massive MIMO system. [ABSTRACT FROM AUTHOR]

Published

2022

37. Simulation of Switched-Mode Power Conversion Circuits With Extended Impedance Method.

Author

Liu, Yichao, Gao, Yiming, and Liang, Junrui

Subjects

POWER electronics, ELECTRIC circuit networks, Q-switched lasers, COMPUTATIONAL complexity, DIFFERENTIAL equations, FREQUENCY-domain analysis

Abstract

Efficient simulation of switched-mode power conversion circuits is necessary for the analysis and optimization of power electronics. This paper introduces the extended impedance method (EIM) to the simulation and analysis of general switched-mode power converter circuits. By using the EIM method, the conventional impedance concept can be extended to involve more linear time-variant (LTV) and nonlinear devices, such as MOSFET switches and diodes, which are commonly used in switched-mode power conversion circuits. EIM models a circuit network from the component level in the frequency domain, rather than from the system-level constitutive differential equation in the time domain. Compared with the conventional averaging method, EIM can reveal more high-frequency features of a switched-mode converter circuit, in particular, those around the switching instants. A buck converter is taken as a representative example to validate the EIM based analysis. Both the simulation and experimental results prove that EIM provides precise numerical results, which match the real waveform, as the commercial simulators, e.g. PSpice and ADS, do. Moreover, it largely reduces the computational complexity towards more efficient and more flexible steady-state analysis of switched-mode power electronics. [ABSTRACT FROM AUTHOR]

Published

2022

38. Mathematical modeling of the electric field in the planar and coaxial dielectric barrier discharge reactor in water treatment application.

Author

Amirbande, Masoume and Vahedi, Abolfazl

Subjects

ELECTRIC fields, WATER purification, SURFACE charges, DIELECTRICS, MATHEMATICAL models, FINITE element method

Abstract

Purpose: To design a pulse power water treatment system, it is necessary to design a reactor optimally. One of the most essential types of reactors used in water treatment is the dielectric barrier discharge (DBD) reactor. The purpose of this paper is to model the electric field in the two types of planar and coaxial reactors to have an accurate analytical formula for using in the optimal design according to the required electric field of the treatment. Design/methodology/approach: The method proposed in this paper focuses on the voltage of different areas in the reactor and different boundary conditions to obtain the surface charge density. In this regard, parameters of the dielectric and treated material, as well as the reactor dimension, have been affected in the equations. To confirm the analytical results, the finite element method simulation has been performed, and it shows the accuracy of this method. Findings: The exact analytical equation of the electric field is found within the discharge zone of the planar and coaxial DBD reactors. These equations can predict the values of different parameters of the reactor required to purify the material before each design and it does not even require simulation. Originality/value: The electric field formula presented in this paper can allow the manufacturers of pulse power water treatment systems to optimize their design easily, cost-effectively and in less time. Also, the formulas provided are completely general and remain effective for all materials. [ABSTRACT FROM AUTHOR]

Published

2022

39. ${{H}_{\infty}}$ Model Reduction for Interval Frequency Negative Imaginary Systems.

Author

Yu, Lanlin and Xiong, Junlin

Subjects

MATHEMATICAL models, SIMULATION methods & models

Abstract

This paper studies an $H_{\infty }$ model reduction problem for interval frequency negative imaginary (IFNI) systems. For a given IFNI system, our goal is to find a reduced-order IFNI system satisfying a pre-specified $H_{\infty }$ approximation error bound over the finite-frequency interval. Necessary and sufficient conditions in terms of matrix inequalities are derived for the existence and construction of an $H_{\infty }$ reduced-order IFNI system. An improved iterative algorithm is provided to solve the matrix inequalities and to minimize the $H_{\infty }$ approximation error. The proposed method is further clarified via the application to the electrical circuits, such as high-order Sallen–Key low-pass filter, piezoelectric tube scanner, and RLC circuit. The simulation results on these electrical circuits are compared with the finite-frequency interval Gramians-based model reduction method both in the frequency domain and time domain. [ABSTRACT FROM AUTHOR]

Published

2019

40. A New Approach to Linear/Nonlinear Distributed Fusion Estimation Problem.

Author

Chen, Bo, Hu, Guoqiang, Ho, Daniel W.C., and Yu, Li

Subjects

ESTIMATION theory, MATHEMATICAL models, LINEAR systems, NONLINEAR systems, MOBILE robots

Abstract

In this paper, we study the distributed fusion estimation problem for linear time-varying systems and nonlinear systems with bounded noises, where the addressed noises do not provide any statistical information, and are unknown but bounded. When considering linear time-varying fusion systems with bounded noises, a new local Kalman-like estimator is designed such that the square error of the estimator is bounded as time goes to $\infty$. A novel constructive method is proposed to find an upper bound of fusion estimation error, then a convex optimization problem on the design of an optimal weighting fusion criterion is established in terms of linear matrix inequalities, which can be solved by standard software packages. Furthermore, according to the design method of linear time-varying fusion systems, each local nonlinear estimator is derived for nonlinear systems with bounded noises by using Taylor series expansion, and a corresponding distributed fusion criterion is obtained by solving a convex optimization problem. Finally, target tracking system and localization of a mobile robot are given to show the advantages and effectiveness of the proposed methods. [ABSTRACT FROM AUTHOR]

Published

2019

41. A novel serial structure repetitive control strategy for shunt active power filter.

Author

Chen, Dongdong, Chen, Hao, Hu, Yaowei, and Chen, Guozhu

Subjects

ELECTRIC power filters, HARMONIC suppression filters, MATHEMATICAL models, HARMONIC analysis (Mathematics), POLES (Engineering)

Abstract

Purpose The purpose of this paper is to propose a novel serial structure repetitive control scheme for shunt active power filter (SAPF) to improve the steady-state accuracy and dynamic performance of SAPF. The novelty of this scheme lies in the reconfiguration of the pole of repetitive control internal model, so that the dynamic response of the repetitive control is improved greatly.Design/methodology/approach By analyzing the mathematical model of repetitive control, the repetitive control delay can reduce by giving up the needless poles of the internal model, and the general mk + i repetitive control can be designed through the pole configuration method. The controller can track a set of specific order harmonics.Findings The experimental results are coincident with the theoretical analyses, which prove the effectiveness of the proposed method on harmonic suppression and great performance in dynamic response.Practical implications An APF prototype has been designed with the serial structure repetitive control proposed in this paper, and it can successfully eliminate the harmonics current of nonlinear load with faster dynamic response. Moreover, the proposed controller can be applied to any three-phase system for fast dynamic response and high tracking accuracy.Originality/value In this paper, the mathematical model of the repetitive control for specific set of harmonica is developed. A novel serial structure repetitive control is designed, so that the SAPF can eliminate the fundamental reactive current and specific order harmonics and speed up the dynamic response of the repetitive control. [ABSTRACT FROM AUTHOR]

Published

2019

42. Modeling and Simulation of Vanadium Dioxide Relaxation Oscillators.

Author

Maffezzoni, Paolo, Daniel, Luca, Shukla, Nikhil, Datta, Suman, and Raychowdhury, Arijit

Subjects

RELAXATION oscillators, VANADIUM dioxide, COMPUTER simulation, VOLTAGE-controlled oscillators, BOOLEAN functions, SIGNAL processing, ARTIFICIAL neural networks, MATHEMATICAL models

Abstract

This paper deals with modeling and simulation of a new family of two-terminal devices fabricated with vanadium dioxide material. Such devices allow realization of very compact relaxation nano-oscillators that can be connected electronically to form arrays of coupled oscillators. Challenging applications of oscillator arrays include the realization of multiphase signal generators and massively parallel brain-inspired neurocomputing. In the paper, a circuit-level model of the vanadium dioxide device is provided which enables extensive electrical simulations of oscillator systems built on the device. The proposed model is exploited to explain the dynamics of vanadium dioxide relaxation oscillators as well as to accomplish a robust parameter design. Applications to the realization of voltage-controlled oscillators and of multiphase oscillator arrays are illustrated. [ABSTRACT FROM AUTHOR]

Published

2015

43. THE 2016 HIMCM.

Author

SNOOK, KATHLEEN

Subjects

WINNERS, MATHEMATICS contests, MATHEMATICAL models, SIMULATION methods & models, HIGH schools

Published

2017

44. Scanning the Issue.

Subjects

AUTOMATIC control systems, NONLINEAR programming, PROGRAMMABLE controllers, INDUSTRIAL controls manufacturing, MATHEMATICAL models, COMMAND & control systems

Abstract

Provides an overview of the technical articles and features presented in this issue. [ABSTRACT FROM PUBLISHER]

Published

2017

45. Deterministic Networked Control of Discrete Event Systems With Nondeterministic Communication Delays.

Author

Shu, Shaolong and Lin, Feng

Subjects

DISCRETE systems, MATHEMATICAL models, COMMAND & control systems, INDUSTRIAL controls manufacturing, PROGRAMMABLE controllers

Abstract

We continue to investigate the impacts of communication delays on networked control of discrete event systems (DES). Our previous results show that nondeterministic communication delays result in nondeterminism in the languages generated by the controlled system, which makes the networked control problems more complex. In this paper we investigate the language nondeterminism. We define delay observability and delay controllability. If the language to be synthesized is delay observable and delay controllable, we can synthesize a networked supervisor to control the DES such that the language generated by the controlled system is deterministic, that is, we can synthesize a “deterministic” state-estimate-based networked supervisor. We derive algorithms to check delay controllability and delay observability. If the language to be synthesized is not delay observable and/or delay controllable, we can find its infimal delay controllable and delay observable superlanguage and maximal delay controllable and delay observable sublanguages. We develop algorithms to find these superlanguages and sublanguages. All the algorithms proposed in the paper are of polynomial computational complexity. [ABSTRACT FROM PUBLISHER]

Published

2017

46. Analog/Digital Multiplierless Implementations for Nullcline-Characteristics-Based Piecewise Linear Hindmarsh-Rose Neuron Model.

Author

Cai, Jianming, Bao, Han, Chen, Mo, Xu, Quan, and Bao, Bocheng

Subjects

NEURONS, ANALOG circuits, GATE array circuits, DIGITAL electronics

Abstract

Multipliers are essential in implementing nonlinear neuron models, but they take huge implementation costs. Many multiplierless fitting schemes have been proposed to simplify the implementation of nonlinearities in neuron models. To optimize these schemes, this paper presents a nullcline-characteristics- based piecewise linear (NC-PWL) fitting scheme for multiplierless implementations of Hindmarsh-Rose (HR) neuron model. This NC-PWL fitting scheme uses as few line segments as possible to approximate the critical nonlinearity characteristics of the local nullclines. A NC-PWL HR neuron model that reproduces diverse firing patterns of the original one is successfully established. Using off-the-shelf low-cost components, an analog multiplierless circuit is designed for this fitting model and welded on print circuit board (PCB). Meanwhile, by logical shift method, a digital multiplierless circuit with low resource consumption is developed for this fitting model on field-programmable gate array (FPGA) platform. Experimental results of the analog and digital multiplierless hardware implementations verify the numerical simulations and show the simplicity and feasibility of the presented fitting scheme. [ABSTRACT FROM AUTHOR]

Published

2022

47. Analysis and Design of Digital Injection-Locked Clock Multipliers Using Bang-Bang Phase Detectors.

Author

Xu, Rongjin, Ye, Dawei, and Shi, C. -J. Richard

Subjects

PHASE detectors, TIME-domain analysis, TRANSFER functions, FEEDBACK control systems, PHASE noise, PHASE-locked loops, NONLINEAR oscillators

Abstract

The analysis of injection-locked clock multipliers (ILCMs) using bang-bang phase detectors (BBPDs) is challenging due to the nonlinear BBPD and the multi-rate injected oscillator. This paper presents an explicit analysis of digital ILCMs using BBPDs and proposed an intuitive approach to optimizing parameters with given noise sources. A time-domain analysis in the single-clock domain is presented to solve the closed-form expression of jitter in the ILCM. The proposed approach exhibits good consistency with simulations, for various design parameters and noise cases. With the predicted input-referred jitter, the equivalent BBPD gain is resolved to derive the frequency-domain noise transfer functions in concise forms. To achieve the desired performance with given specifications, recommended design procedures are summarized based on the proposed analysis and verified by simulations. [ABSTRACT FROM AUTHOR]

Published

2022

48. Adaptive Boundary Observer Design for Coupled Parabolic PDEs With Different Diffusions and Parameter Uncertainty.

Author

Ji, Chunting and Zhang, Zhengqiang

Subjects

REACTION-diffusion equations, PARTIAL differential equations, TUBULAR reactors, PARABOLIC differential equations, CHEMICAL reactors, ANALYTICAL chemistry, NONLINEAR dynamical systems

Abstract

This paper focuses on establishing an adaptive boundary observer for fully coupled reaction-diffusions partial differential equations (PDEs) containing unknown parameters. Firstly, the state error system is transformed into an intermediate system by finite dimensional backstepping-like transformation, and then we convert the intermediate system to a target system by infinite dimensional backstepping transformation. Secondly, a least-squares type parameter adaptive law is given. Thirdly, exploiting an ad hoc persistent excitation condition, the exponentially convergent of the observer will be established by applying Lyapunov functional. Finally, we use simulation analysis for Chemical Tubular Reactor model to demonstrate the validity of the results. [ABSTRACT FROM AUTHOR]

Published

2022

49. INTERNATIONAL MATHEMATICAL MODELING CHALLENGE.

Subjects

MATHEMATICAL models, CROWDS

Published

2020

50. A New Representation of FFT Algorithms Using Triangular Matrices.

Author

Garrido, Mario

Subjects

FAST Fourier transforms, ALGORITHM research, TRIANGULARIZATION (Mathematics), FLOWGRAPHS, COMPUTER architecture, MATHEMATICAL models

Abstract

In this paper we propose a new representation for FFT algorithms called the triangular matrix representation. This representation is more general than the binary tree representation and, therefore, it introduces new FFT algorithms that were not discovered before. Furthermore, the new representation has the advantage that it is simple and easy to understand, as each FFT algorithm only consists of a triangular matrix. Besides, the new representation allows for obtaining the exact twiddle factor values in the FFT flow graph easily. This facilitates the design of FFT hardware architectures. As a result, the triangular matrix representation is an excellent alternative to represent FFT algorithms and it opens new possibilities in the exploration and understanding of the FFT. [ABSTRACT FROM PUBLISHER]

Published

2016