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35,488 results on '"Dead time"'

3. Revisiting the dead time effects of Insight-HXMT/ME on timing analysis

Author

Tuo, Youli, Li, Xiaobo, Tan, Ying, Wu, Baiyang, Jiang, Weichun, Song, Liming, Qu, Jinlu, Gogate, Sudeep, Zhang, Shuang-Nan, and Santangelo, Andrea

Subjects
Astrophysics - High Energy Astrophysical Phenomena
Abstract

Dead time is a common instrumental effect of X-ray detectors which would alter the behavior of timing properties of astronomical signals, such as distorting the shape of power density spectra (PDS), affecting the root-mean-square of potential quasi-periodic oscillation signals, etc. We revisit the effects of the dead time of Medium Energy X-ray telescope (ME) onboard Insight-HXMT, based on the simulation of electronic read-out mechanism that causes the dead time, and the real data. We investigate dead time effects on the pulse profile as well as the Quasi-Periodic Oscillation (QPO) signals. The dead time coefficient suggests a linear correlation with the observed count rate in each phase bin of the pulse profile according to the simulation of periodic signal as well as the real data observed on Swift J0243.6+6124. The Fourier-amplitude-difference (FAD) method could well recover the intrinsic shape of the observed PDS in the case that the PDS is from two identical detectors. We apply this technique on ME, by splitting the 9 FPGA modules into 2 groups. The results indicate that the FAD technique suits the case when two groups of detectors are not largely different; and the recovered PDS of Sco X-1 observed by ME slightly enhances the significance of the previously known QPO signal, meanwhile the root-mean-square of QPO is significantly improved. We provide the FAD correction tool implemented in HXMTDAS for users in the future to better analyze QPO signals., Comment: 9 pages, 8 figures, accepted for publication in MNRAS main journal

Published
2024

4. Dead‐time compensation for PMSM with phase shift of impedance considered based on adaptive linear neuron method

Author

Jinhai Liu and Huanting Chen

Subjects
ADALINE, Dead‐time Compensation, permanent magnet synchronous motor, Applications of electric power, TK4001-4102
Abstract

Abstract A new adaptive‐linear‐neuron‐ (ADALINE‐) based dead‐time compensation method is presented for permanent magnet synchronous motor (PMSM) drives. It is proposed to suppress the sixth current harmonics adaptively in the synchronous reference frame due to dead‐time effects. In order to extract the sixth current harmonics, two ADALINE‐based extractors are used without taking into account the electrical lead angle. An improved ADALINE algorithm is used to calculate compensation voltages, taking into account the phase shift of impedance. The proposed method is capable of operating not only at low speed but also at medium and rated speeds in contrast to the traditional compensation method of ADALINE only at low speed. The new method is effective in steady, load dynamic and speed dynamic states with no needs for any extra hardware to detect phase current polarity. The effectiveness of the proposed compensation method is verified on a 780 W PMSM drive through experiments.

Published
2024
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5. Dead time effects compensation strategy by third harmonic injection for a five-phase inverter

Author

Krzysztof Łuksza, Dmytro Kondratenko, and Arkadiusz Lewicki

Subjects
dead-time effects, field-oriented control, five-phase voltage source inverter, ipmsm, sensorless control, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

This paper proposes a method for compensation of dead-time effects for a fivephase inverter. In the proposed method an additional control subsystem was added to the field-oriented control (FOC) scheme in the coordinate system mapped to the third harmonic. The additional control loop operates in the fixed, orthogonal reference frame ( α - β coordinates) without the need for additional Park transformations. The purpose of this method is to minimize the dead-time effects by third harmonic injection in two modes of operation of the FOC control system: with sinusoidal supply and with trapezoidal supply. The effectiveness of the proposed control method was verified experimentally on a laboratory setup with a prototype five-phase interior permanent magnet synchronous machine (IPMSM). All experimental results were presented and discussed in the following paper.

Published
2024
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8. A Technical Review on IMC-PID Design for Integrating Process With Dead Time

Author

K. Divakar, M. Praveen Kumar, Dhanamjayulu C, and Gokulakrishnan G

Subjects
Dead time, IMC, integrating process, maximum sensitivity, PID, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The demeanour of many chemical and non-chemical processes resemble that of an integrating process. Developing a control plan for an integrating process is complicated, and the difficulty becomes even more when dead time is present. Internal Model Control (IMC) is enthralling in the creation of control strategies because it can derive the controller in the framework of a Proportional-Integral-Derivative controller (PID). It has been noted that when a filter is added to a controller, its performance improves, and various researchers have proposed PID with filter. The current work presents a comprehensive review of existing IMC-PID controllers for controlling integrating processes with dead time. The filter postulation in IMC is discussed, which is responsible for generating several forms of PID for the same process. Performance is measured using a variety of conventional performance indices. This article provides an overview of IMC filter topologies used in IMC-PID tuning for various integrating processes, including tuning relations and time delay approximations. The paper has also highlighted the guidelines for the selection of IMC filter and different structures of IMC filters from conventional to fractional order.

Published
2024
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9. Influence of Reverse Conduction on Dead Time Selection in GaN-Based Inverters for AC Motor Drives

Author

S. Musumeci, V. Barba, F. Stella, F. Mandrile, M. Palma, and R. Bojoi

Subjects
GaN FET, MOSFET, dead time, reverse conduction, body diode, inverter drive, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Although Gallium Nitride (GaN) Field Effect Transistor (FET) devices have found extensive application in DC-DC converters, their utilization in inverter motor drives remains an evolving area of study. In particular, the intricacies of reverse conduction operation during the dead time, specific to GaN FETs, require in-depth exploration for inverters supplying AC currents to electrical motors. Therefore, this paper undertakes an assessment of reverse conduction during the dead time intervals in low-voltage GaN FETs employed in motor drives applications. This analysis provides correlations between device technology attributes and the variations in AC phase current. To facilitate this investigation, a dedicated numerical tool is developed to evaluate the reverse conduction characteristics of GaN FET and associated power losses. Furthermore, this study includes a comparative analysis of the reverse conduction behavior of GaN FET devices with their low-voltage MOSFET counterparts, taking into account their differing static and dynamic characteristics. As a result, the main contribution of this work is to provide to the inverter designers a comprehensive understanding of dead-time effects in GaN-based inverters, along with guidance on selecting and optimizing dead time intervals within inverter legs for motor control applications employing the latest generation of GaN FET devices.

Published
2024
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10. Adaptive Dead-Time Modulation Scheme for Bidirectional LLC Resonant Converter in Energy Router

Author

Chenghao Sun, Qiuye Sun, Rui Wang, Yuyang Li, and Dazhong Ma

Subjects
Adaptive modulation, bidirectional LLC, body diode loss, dead-time, energy router, ZVS, Technology, Physics, QC1-999
Abstract

Although the dead-time optimization design of resonant converters has been widely researched, classical design methods focus more on achieving zero-voltage switching (ZVS) operation. The body diode loss is always ignored, which results in low-efficiency of the converter, especially, in energy router (ER). To deal with this problem, this paper proposes an adaptive deadtime modulation scheme for bidirectional LLC resonant converters in ER. First, the power loss of the MOSFET is analyzed based on the dead-time. Then, a novel dead-time optimization modulation principle is proposed. It can eliminate the body diode loss of MOSFET compared with existing literature. Based on the optimization modulation principle, this paper proposes an adaptive dead-time modulation scheme. To this end, the converter adopting the scheme no longer needs to calculate dead-time, which simplifies the parameter design process. Meanwhile, this scheme enables dead-time to dynamically change with working conditions according to the dead-time optimization modulation principle. With these effects, the ZVS operation is achieved, and the body diode loss of MOSFET is also eliminated. Furthermore, a digital implementation method is designed to make the proposed modulation scheme have fast-transient response. Finally, experimental results show that the proposed dead-time modulation scheme enables converters to achieve ZVS operation in all working conditions, and has higher efficiency than classical dead-time design methods.

Published
2024
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11. Mixed Dead-Time Effect Suppression Strategy for Modular Multilevel Converters

Author

Zhi Geng and Minxiao Han

Subjects
Dead-time effect, modular multilevel converters, switching frequency, voltage balancing algorithm, Technology, Physics, QC1-999
Abstract

Dead time is necessary for the coupled power switches to prevent shoot-through, especially in the modular multilevel converters (MMCs) with a large number of power switches. This paper proposes a dead-time effect suppression strategy for MMCs with nearest level modulation. The operational principles of MMCs are first analyzed. According to the operational features of MMCs, the method that removes a switching signal from the coupled switches and the reduced switching frequency voltage balancing algorithms (RSFVBAs) are mixed in the proposed method. In the intervals that are furthest away from the zero-crossing points (ZCP) of arm currents, the single switching signal method can completely eliminate the dead-time effect (DTE). Alternatively, the DTE is suppressed by the RSFVBA in intervals that are close to the ZCP. By the combination of the two methods, the dependence of the DTE suppression method on currents is reduced and the influences of ZCP are also released without degrading the normal operation performance of MMCs. Moreover, the output performance of MMCs is improved and the voltage stress on the arm inductor dramatically decreases. Finally, the validation of the method is verified by the simulation results with the professional tool Matlab/Simulink.

Published
2024
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12. Active elimination of DC bias current of a SiC based dual active bridge by controlling the dead time period

Author

Ganesan Perumal, Kamalesh Hatua, and Manju Rajagopal

Subjects
AC–DC power convertors, DC–AC power convertors, DC–DC power convertors, Electronics, TK7800-8360
Abstract

Abstract Dual active bridge (DAB) is an isolated DC‐DC converter gaining wider attention in power electronics applications. The high frequency (HF) transformer is an integral part of the DAB which is prone to saturation. Silicon carbide (SiC) based DAB are generally preferred for highly efficient power conversions, calling for an extremely low DC resistance of the transformer. This aggravates the DC bias issue significantly. The DC bias current generally flows due to the mismatch in static and transient switching of active devices, leading to eventual saturation of the transformer. This paper proposes an active method to precisely control the dead time of the devices (8–100 ns) without sacrificing the voltage utilization of the converter. This method does not require a sophisticated DC offset current measurement technique. The field programmable gate array (FPGA) based control platform on the gate driver side executes the proposed algorithm. The proposed control is experimentally verified in a 5 kW SiC based converter. The control implementation methodology is discussed with the support of necessary experimental results.

Published
2024
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13. Dead-time Compensation Method for Bus-clamping Modulated Voltage Source Inverter

Author

Ghaderloo, Reza Asrar, Shen, Yidi, Singhabahu, Chanaka, Resalayyan, Rakesh, and Khaligh, Alireza

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Bus-clamping Pulse Width Modulation (PWM) is an effective method to reduce the switching loss in a three-phase voltage source inverter (VSI). In bus-clamping PWM scheme, the phase legs are switched using high frequency PWM signals for two-third of the line cycle, while for the remaining duration of cycle, the pole voltage is clamped to either positive or negative rail of the DC bus. In PWM operation of a half bridge, a dead-time is applied between the gate signals of complementary switches to ensure safe and reliable operation. However, introduction of dead-time leads to poor power quality, increased Total Harmonic Distortion (THD) and variation in actual voltage compared to the intended pole voltage. Moreover, when the bus-clamping technique is used, the PWM has both high frequency switching region and clamped region in a line cycle, and consequently, the undesired effects of dead-time are further aggravated. Therefore, in order to enhance the quality of output voltage, this paper presents a dead-time compensation strategy for a VSI operating with bus-clamping PWM. The proposed method calculates the required compensation term to be added on the modulation signal considering wide range of operating conditions. Additionally, the compensation includes a new strategy for low current conditions near zero-crossing to avoid distortion. The proposed method is verified by simulation and experiments in a three-phase VSI with a switching frequency of 100 kHz and a fundamental frequency of 60Hz., Comment: I will make some major changes on the paper. I prefer to withdraw it for now

Published
2023

14. Dead-time optimization to increase secure distance range in prepare and measure quantum key distribution protocols

Author

Wiechers, Carlos, Lucio, J. L., Sánchez-Lozano, Xóchitl, Gómez-Medina, Rafael, and Salado-Mejía, Mariana

Subjects
Quantum Physics
Abstract

Afterpulsing is a factor limiting the distance over which discrete-variable quantum key distribution systems are secure, and a common feature in single-photon detectors. The relevance of this phenomenon stems from its stochastic, self-interacting nature and the fact that its rate rises with the number of avalanche events, which increases the quantum bit error rate. Here we introduce an effective analytic model, including dead-time and afterpulsing corrections, where afterpulsing correction depends on dead-time value. This model is useful to evaluate the performance of prepare and measure quantum key distribution protocols (standard and decoy versions) that use gated single photon detectors. The model provides an expression to numerically optimize the secret key rate over the full distance range for secure communication, enabling in this way the calculation of quantum bit error rate and secure key rate. In the conventional procedure, the dead-time value is fixed regardless of distance, limiting the distance range of the channel due to remaining afterpulsing effects, which are more relevant at higher operating frequencies. Here we demonstrate that optimizing the dead-time values increases the distance range of the channel to share secret keys., Comment: 13 pages, 9 figures

Published
2023

16. A new adaptive dead time compensation method for dual three-phase permanent magnet synchronous motor

Author

Xuefeng Zhang, Qiwei Xu, Yiming Wang, Lingyan Luo, and Yun Yang

Subjects
Dual three phase, Current harmonics, Dead time, Adaptive compensation method, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

This paper proposes a new adaptive dead time compensation method for dual three-phase permanent magnet synchronous motors with two sets of three-phase windings spatially shifted by 30 electrical degrees. The stator resistance and leakage inductance are the only 5th and 7th harmonic impedances in the dual three-phase motor, which leads to a more pronounced current distortion due to dead time in the dual three-phase motor than in the three-phase motor. Therefore, dead-time compensation has significant implications for the application of dual three-phase motors. In this paper, the minimum value tracking algorithm is used to adjust the compensation voltage amplitude adaptively, and the compensation voltages are added to the output reference voltage in stationary frames. The proposed computation method has some significant advantages, such as simple implementation without additional hardware, easy mathematical computations, and no offline experimental measurements. Simulation results are provided to validate the performance of the proposed method.

Published
2023
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17. Identification of heart rate dynamics during treadmill and cycle ergometer exercise: the role of model zeros and dead time [version 2; peer review: 2 approved with reservations]

Author

Kenneth J. Hunt and Hanjie Wang

Subjects
Brief Report, Articles, heart rate dynamics, system identification, treadmill exercise, cycle ergometer exercise
Abstract

Background The response of heart rate to changes in exercise intensity is comprised of several dynamic modes with differing magnitudes and temporal characteristics. Investigations of empirical identification of dynamic models of heart rate showed that second-order models gave substantially and significantly better model fidelity compared to the first order case. In the present work, we aimed to reanalyse data from previous studies to more closely consider the effect of including a zero and a pure delay in the model. Methods This is a retrospective analysis of 22 treadmill (TM) and 54 cycle ergometer (CE) data sets from a total of 38 healthy participants. A linear, time-invariant plant model structure with up to two poles, a zero and a dead time is considered. Empirical estimation of the free parameters was performed using least-squares optimisation. The primary outcome measure is model fit, which is a normalised root-mean-square model error. Results A model comprising parallel connection of two first-order transfer functions, one with a dead time and one without, was found to give the highest fit (56.7 % for TM, 54.3 % for CE), whereby the non-delayed component appeared to merely capture initial transients in the data and the part with dead time likely represented the true dynamic response of heart rate to the excitation. In comparison, a simple first-order model without dead time gave substantially lower fit than the parallel model (50.2 % for TM, 47.9 % for CE). Conclusions This preliminary analysis points to a linear first-order system with dead time as being an appropriate model for heart rate response to exercise using treadmill and cycle ergometer modalities. In order to avoid biased estimates, it is vitally important that, prior to parameter estimation and validation, careful attention is paid to data preprocessing in order to eliminate transients and trends.

Published
2024
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18. Photocounting measurements with dead time and afterpulses in the continuous-wave regime

Author

Semenov, A. A., Samelin, J., Boldt, Ch., Schünemann, M., Reiher, C., Vogel, W., and Hage, B.

Subjects
Quantum Physics, Physics - Instrumentation and Detectors
Abstract

The widely used experimental technique of continuous-wave detection assumes counting pulses of photocurrent from a click-type detector inside a given measurement time window. With such a procedure we miss out the photons detected after each photocurrent pulse during the detector dead time. Additionally, each pulse may initialize so-called afterpulse, which is not associated with the real photons. We derive the corresponding quantum photocounting formula and experimentally verify its validity. Statistics of photocurrent pulses appears to be nonlinear with respect to quantum state, which is explained by the memory effect of the previous measurement time windows. Expressions -- in general, nonlinear -- connecting statistics of photons and pulses are derived for different measurement scenarios. We also consider an application of the obtained results to quantum state reconstruction with unbalanced homodyne detection., Comment: 23 pages, 19 figures

Published
2023
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19. Investigation of Dead Time Losses in Inverter Switching Leg Operation: GaN FET vs. MOSFET Comparison

Author

Vincenzo Barba, Salvatore Musumeci, Fausto Stella, Fabio Mandrile, and Marco Palma

Subjects
motor drive, inverter leg, dead time, switching losses, reverse conduction, GaN FET, Technology
Abstract

This paper investigates the commutation transients of MOSFET and GaN FET devices in motor drive applications during hard-switching and soft-switching commutations at dead time operation. This study compares the switching behaviors of MOSFETs and GaN FETs, focusing on their performance during dead time in inverter legs for voltage source inverters. Experimental tests at various phase current levels reveal distinct switching characteristics and energy dissipation patterns. A validated simulation model estimates the experimental energy exchanged and dissipated during switching transients. The results demonstrate that GaN FETs exhibit lower overall losses at shorter dead times compared to MOSFETs, despite higher reverse conduction voltage drops. The study provides a quantitative framework for selecting optimal dead times to minimize energy losses, enhancing the efficiency of GaN FET-based inverters in low-voltage motor drive applications. Finally, a dead time optimization strategy is proposed and described.

Published
2024
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20. Dead‐time compensation for PMSM with phase shift of impedance considered based on adaptive linear neuron method.

Author

Liu, Jinhai and Chen, Huanting

Abstract

A new adaptive‐linear‐neuron‐ (ADALINE‐) based dead‐time compensation method is presented for permanent magnet synchronous motor (PMSM) drives. It is proposed to suppress the sixth current harmonics adaptively in the synchronous reference frame due to dead‐time effects. In order to extract the sixth current harmonics, two ADALINE‐based extractors are used without taking into account the electrical lead angle. An improved ADALINE algorithm is used to calculate compensation voltages, taking into account the phase shift of impedance. The proposed method is capable of operating not only at low speed but also at medium and rated speeds in contrast to the traditional compensation method of ADALINE only at low speed. The new method is effective in steady, load dynamic and speed dynamic states with no needs for any extra hardware to detect phase current polarity. The effectiveness of the proposed compensation method is verified on a 780 W PMSM drive through experiments. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Identification of heart rate dynamics during treadmill and cycle ergometer exercise: the role of model zeros and dead time [version 2; peer review: 2 approved]

Author

Hanjie Wang and Kenneth J. Hunt

Subjects
heart rate dynamics, system identification, treadmill exercise, cycle ergometer exercise, eng, Medicine, Science
Abstract

Background The response of heart rate to changes in exercise intensity is comprised of several dynamic modes with differing magnitudes and temporal characteristics. Investigations of empirical identification of dynamic models of heart rate showed that second-order models gave substantially and significantly better model fidelity compared to the first order case. In the present work, we aimed to reanalyse data from previous studies to more closely consider the effect of including a zero and a pure delay in the model. Methods This is a retrospective analysis of 22 treadmill (TM) and 54 cycle ergometer (CE) data sets from a total of 38 healthy participants. A linear, time-invariant plant model structure with up to two poles, a zero and a dead time is considered. Empirical estimation of the free parameters was performed using least-squares optimisation. The primary outcome measure is model fit, which is a normalised root-mean-square model error. Results A model comprising parallel connection of two first-order transfer functions, one with a dead time and one without, was found to give the highest fit (56.7 % for TM, 54.3 % for CE), whereby the non-delayed component appeared to merely capture initial transients in the data and the part with dead time likely represented the true dynamic response of heart rate to the excitation. In comparison, a simple first-order model without dead time gave substantially lower fit than the parallel model (50.2 % for TM, 47.9 % for CE). Conclusions This preliminary analysis points to a linear first-order system with dead time as being an appropriate model for heart rate response to exercise using treadmill and cycle ergometer modalities. In order to avoid biased estimates, it is vitally important that, prior to parameter estimation and validation, careful attention is paid to data preprocessing in order to eliminate transients and trends.

Published
2024
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22. Adaptive Synchronous Rectifier On-Time Control Within Dead-Time for Improving Light-Load Performance of LLC Resonant Converters

Author

Sun, Chenghao, Sun, Qiuye, Zhu, Tianhua, Wang, Rui, Zhao, Fangzhou, Wang, Pengcheng, Wang, Xiongfei, Sun, Chenghao, Sun, Qiuye, Zhu, Tianhua, Wang, Rui, Zhao, Fangzhou, Wang, Pengcheng, and Wang, Xiongfei

Abstract

LLC resonant converter exhibits nonmonotonic voltage gain at light-load, which could lead to the malfunction of traditional pulse frequency modulation strategy and degraded efficiency due to excessive increase in switching frequency. To address this issue, an adaptive synchronous rectifier (SR) on-time control within dead-time is proposed for LLC resonant converters to normalize the voltage gain and enhance the light-load efficiency. First, the root cause of nonmonotonic voltage gain is analyzed and revealed as the energy accumulated in resonant inductor due to mismatched output capacitor discharge between primary and secondary side switches within dead-time. To suppress the energy accumulation, an adaptive SR on-time control within dead-time is developed to synchronize the output capacitor discharge processes of primary and secondary side switches, which is characterized as: 1) SR is turned on within dead-time to accelerate its output capacitor discharge; 2) the turn-on rate of SR is controlled by designing its gate resistor to match the output capacitor discharge rate of primary side switches; 3) the turn-on instant of SR is adaptively tuned according to the switching frequency. With the proposed SR control, the energy accumulation of resonant inductor during output capacitor discharge of switches is fully suppressed, resulting in a monotonic voltage gain at light-load, which facilitates voltage regulation and improves light-load efficiency. A 360-440-V input, 50-V/1-kW output LLC prototype is built to verify the effectiveness of proposed SR control., QC 20240822

Published
2024
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26. Dark Current and Single Photon Detection by 1550nm Avalanche Photodiodes: Dead Time Corrected Probability Distributions and Entropy Rates

Author

Menkart, Nicole, Hart, Joseph D., Murphy, Thomas E., and Roy, Rajarshi

Subjects
Physics - Optics, Physics - Instrumentation and Detectors, Quantum Physics
Abstract

Single photon detectors have dark count rates that depend strongly on the bias level for detector operation. In the case of weak light sources such as novel lasers or single-photon emitters, the rate of counts due to the light source can be comparable to that of the detector dark counts. In such cases, a characterization of the statistical properties of the dark counts is necessary. The dark counts are often assumed to follow a Poisson process that is statistically independent of the incident photon counts. This assumption must be validated for specific types of photodetectors. In this work, we focus on single-photon avalanche photodiodes (SPADs) made for 1550nm. For the InGaAs detectors used, we find the measured distributions often differ significantly from Poisson due to the presence of dead time and afterpulsing with the difference increasing with the bias level. When the dead time is increased to remove the effects of afterpulsing, it is necessary to correct the measured distributions for the effects of the dead time. To this end, we apply an iterative algorithm to remove dead time effects from the probability distribution for dark counts as well as for the case where light from an external weak laser source (known to be Poisson) is detected together with the dark counts. We believe this to be the first instance of the comprehensive application of this algorithm to real data and find that the corrected probability distributions are Poisson distributions in both cases. We additionally use the Grassberger-Procaccia algorithm to estimate the entropy production rates of the dark count processes, which provides a single metric that characterizes the temporal correlations between dark counts as well as the shape of the distribution. We have thus developed a systematic procedure for taking data with 1550nm SPADs and obtaining accurate photocount statistics to examine novel light sources., Comment: 14 pages, 8 figures

Published
2022
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27. Innovative dead-time correction and background subtraction for neutron multiplicity measurements using neural networks

Author

Jeremias Garcia-Duarte, Yonatan Mishnayot, Aaron S. Tamashiro, Jackson R. Lawrence, and Jason T. Harke

Subjects
Medicine, Science
Abstract

Abstract The number of neutrons emitted from a nuclear reaction plays a crucial role in various fields, including nuclear theory, nuclear nonproliferation, nuclear energy and nuclear criticality safety. Accurate determination of neutron multiplicities requires the application of several corrections, with dead-time correction and background subtraction being particularly significant. These corrections become more challenging for neutron detectors with time-dependent neutron capture. In this work, we perform a comprehensive study of three existing methods used for dead-time correction and background subtraction in neutron detectors with time-dependent neutron capture. The methods were tested for dead-times in the range from 0 to 1 μs using a Monte Carlo model simulating the dead-time and background effects in the standard neutron multiplicity probability distribution of $$^{252}$$ 252 Cf. The previous methods showed larger than desired uncertainty or systematic trade off. Those uncertainties prompted the development of a novel approach using neural networks trained with data from Monte Carlo simulations. The Neural Network method enabled the correction of neutron multiplicity probabilities more accurately than the other methods with fractional errors smaller than 3% for multiplicities around the peak of $$^{252}$$ 252 Cf. A similar approach using neural networks could be applied to problems where the system being studied can be accurately simulated without having an accurate analytical description available. The neural network method presented in this paper can be easily expanded if multiplicities greater than 10 are expected.

Published
2024
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28. A low dead time, resource efficient encoding method for FPGA based high-resolution TDL TDCs

Author

Dong, Wenhao, Feng, Changqing, Wang, Junchen, Shen, Zhongtao, Liu, Shubin, and An, Qi

Subjects
Physics - Space Physics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

This paper presents a novel encoding method for fine time data of a tapped delay line (TDL) time-to-digital Converter (TDC). It is based on divide-and-conquer strategy, and has the advantage of significantly reducing logic resource utilization while retaining low dead-time performance. Furthermore, the problem of high bubble depth in advanced devices can be resolved with this method. Four examples are demonstrated, which were implemented in a Xilinx Artix-7 Field Programmable Gate Array (FPGA) device, and encoding method presented in this paper was employed to encode fine time data for normal TDL TDC, a half-length delay line TDC, and double-edge and four-edge wave union TDCs. Compared with TDCs from the latest published papers that adopt traditional encoders, the logic utilization of TDCs in this paper were reduced by a factor of 45% to 70% in different situations, while the encoding dead time can be restricted in one clock cycle. Acceptable resolutions of the demonstrated TDCs were also obtained, proving the functionality of the encoding method.

Published
2022

30. Identification of heart rate dynamics during treadmill and cycle ergometer exercise: the role of model zeros and dead time [version 1; peer review: awaiting peer review]

Author

Kenneth J. Hunt and Hanjie Wang

Subjects
Brief Report, Articles, heart rate dynamics, system identification, treadmill exercise, cycle ergometer exercise
Abstract

Background The response of heart rate to changes in exercise intensity is comprised of several dynamic modes with differing magnitudes and temporal characteristics. Investigations of empirical identification of dynamic models of heart rate showed that second-order models gave substantially and significantly better model fidelity compared to the first order case. In the present work, we aimed to reanalyse data from previous studies to more closely consider the effect of including a zero and a pure delay in the model. Methods This is a retrospective analysis of 22 treadmill (TM) and 54 cycle ergometer (CE) data sets from a total of 38 healthy participants. A linear, time-invariant plant model structure with up to two poles, a zero and a dead time is considered. Empirical estimation of the free parameters was performed using least-squares optimisation. The primary outcome measure is model fit, which is a normalised root-mean-square model error. Results A model comprising parallel connection of two first-order transfer functions, one with a dead time and one without, was found to give the highest fit (56.7 % for TM, 54.3 % for CE), whereby the non-delayed component appeared to merely capture initial transients in the data and the part with dead time likely represented the true dynamic response of heart rate to the excitation. In comparison, a simple first-order model without dead time gave substantially lower fit than the parallel model (50.2 % for TM, 47.9 % for CE). Conclusions This preliminary analysis points to a linear first-order system with dead time as being an appropriate model for heart rate response to exercise using treadmill and cycle ergometer modalities. In order to avoid biased estimates, it is vitally important that, prior to parameter estimation and validation, careful attention is paid to data preprocessing in order to eliminate transients and trends.

Published
2024
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31. Dead-Time Compensation Using ADALINE for Reduced-Order Observer-Based Sensorless SynRM Drives

Author

Liangnian Lv, Ziyuan Wang, Xinru Zhao, Rui Guo, Jinpeng Wang, Gaolin Wang, and Shulin Li

Subjects
synchronous reluctance motor, adaptive linear neurons, dead-time compensation, reduced-order observer, Technology
Abstract

The inverter dead time effect is non-negligible for the control performance of sensorless synchronous reluctance motor (SynRM) drives at low speeds. In this paper, a reduced-order observer-based sensorless control method for SynRM drives combined with the adaptive linear neurons (ADALINE)-based dead-time compensation is proposed. The reduced-order observer-based sensorless control method is presented, for which is parameter tuning is easy. On this basis, the dead-time compensation strategy using ADALINE filters is proposed to reduce the voltage harmonics effect on the estimation performance of the reduced-order observer. With ADALINE filters, the sixth current harmonic can be successfully filtered out by compensating the voltage directly or fitting the current to compensate the voltage. In this way, the low-speed estimation performance of the reduced-order observer is improved. The effectiveness of the proposed method is verified on a 3 kW SynRM experimental platform.

Published
2024
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34. Current-zero-crossing Shift for Compensation of Dead-time Distortion in Pulse-width-modulated Voltage Source Inverter

Author

Chatterjee Dipankar, Chakraborty Chandan, Mukherjee Kaushik, and Dalapati Suvarun

Subjects
compensation, current polarity, current-zero-crossing shift, dead-time distortion, pwm vsi, Electronics, TK7800-8360
Abstract

Accurate current polarity detection is a major issue for successful compensation of dead-time distortion in pulse-width-modulated (PWM) voltage source inverter. The present study is concerned with the concept of shift in current-zero-crossing due to dead-time distortion compensation that results in error in current polarity detection and thus causes a problem with regard to the successful continuation of compensation. The phenomenon is analysed in detail, along with its dependence on different factors. The proposed concept is validated in digital simulation and also through experimental verification. The study also recommends the possible correction to be incorporated in view of such zero-crossing shift for achieving proper compensation, especially in case of current-sensor-less compensation techniques.

Published
2023
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35. Dead-Time Impact on the Harmonic Distortion and Conversion Efficiency in a Three-Phase Five-Level Cascaded H-Bridge Inverter: Mathematical Formulation and Experimental Analysis

Author

Giuseppe Schettino, Antonino Oscar Di Tommaso, Rosario Miceli, Claudio Nevoloso, Gioacchino Scaglione, and Fabio Viola

Subjects
Dead time, harmonic distortion, efficiency, multilevel inverter, multi carrier PWM, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

To avoid leg short-circuit in inverters, dead time must be introduced on leg gate signals. Dead time affects the inverter output voltage fundamental harmonic amplitude, voltage harmonic distortion and inverter efficiency by introducing additional voltage drops. In this regard, dead time effects have been widely investigated for traditional two-level three-phase voltage source inverters in the literature but not extensively for multilevel topology structures. This paper provides a detailed analysis of dead time impact on the harmonic distortion and efficiency of Cascaded H-Bridges Multilevel Inverters (CHBMIs). For this purpose, a general mathematical formulation to determine voltage drop due to dead time effects, also taking into account the adopted Multicarrier PWM strategy, has been provided and experimentally validated for a five-level three-phase CHBMI structure. As a comparison tool between expected and ideal inverter output voltage, the percentage voltage error $e_{\%}$ is introduced. In most of the cases, $e_{\%} $ is lower than 5%, and it starts increasing for very low amplitude modulation index or for specific working points where nonlinearities occur. Furthermore, several experimental investigations have been carried out to evaluate the CHBMI performance in terms of harmonic distortion and efficiency by changing, the values of dead time, modulation index and switching frequency for ten different multi-carried PWM strategies. Experimental results confirm the strong dependency between the dead time impact on the converter performance and the adopted Multi Carrier-PWM (MC-PWM) strategy: as a way of example, converter efficiency can be reduced from 80% to 60% when dead time is increased from $0.5 \mu \text{s}$ to $1.5 \mu \text{s}$ and Phase Shifted-PWM (PS-PWM) is adopted.

Published
2023
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36. Regulating the DC Voltage of Capacitive Divider Through Variable Switching Dead-Time in the Three-Phase Inverter With an Active Filter

Author

Jin Huang and Kaicheng Li

Subjects
Active filter, capacitive voltage divider, common-mode voltage, inverters, switching dead-time, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In three-phase inverters, high output common-mode voltage (CMV) will bring many negative effects. The active filter with a capacitive voltage divider (CVD) can effectively suppress the peaks of CMV both in the time-domain and frequency-domain. In practice, it is found that the dc voltage of active filter from the CVD will deviate. In this paper, it is found that the deviation comes from the switching dead-time of the active filter. Based on the study in regard to the influence of switching dead-time on the dc voltage of CVD, a variable switching dead-time (VSDT) scheme is proposed. The VSDT scheme can make the voltage of CVD approach the ideal voltage and lead the maximum spectral peak of the CMV to the lowest. The feasibility and effectiveness of the VSDT scheme are verified by the simulations and experiments in a three-phase inverter.

Published
2023
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38. Investigation of Dead Time Losses in Inverter Switching Leg Operation: GaN FET vs. MOSFET Comparison.

Author

Barba, Vincenzo, Musumeci, Salvatore, Stella, Fausto, Mandrile, Fabio, and Palma, Marco

Subjects
*IDEAL sources (Electric circuits), *GALLIUM nitride, *METAL oxide semiconductor field-effect transistors, *SIMULATION methods & models, *QUANTITATIVE research
Abstract

This paper investigates the commutation transients of MOSFET and GaN FET devices in motor drive applications during hard-switching and soft-switching commutations at dead time operation. This study compares the switching behaviors of MOSFETs and GaN FETs, focusing on their performance during dead time in inverter legs for voltage source inverters. Experimental tests at various phase current levels reveal distinct switching characteristics and energy dissipation patterns. A validated simulation model estimates the experimental energy exchanged and dissipated during switching transients. The results demonstrate that GaN FETs exhibit lower overall losses at shorter dead times compared to MOSFETs, despite higher reverse conduction voltage drops. The study provides a quantitative framework for selecting optimal dead times to minimize energy losses, enhancing the efficiency of GaN FET-based inverters in low-voltage motor drive applications. Finally, a dead time optimization strategy is proposed and described. [ABSTRACT FROM AUTHOR]

Published
2024
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39. A modified Smith predictor based – Sliding mode control approach for integrating processes with dead time

Author

Jorge Espín, Fabio Castrillon, Hugo Leiva, and Oscar Camacho

Subjects
Sliding mode controller, Integrating processes, Dead time, Smith predictor, Engineering (General). Civil engineering (General), TA1-2040
Abstract

This paper proposes a modified hybrid robust Smith predictor controller design for integrating processes with long dead time. The proposal results in a dynamic sliding mode controller for integrating systems on blending sliding mode control and Smith Predictor modification concepts. The design part of the controller corresponding to the sliding mode arises from an approximate model of the high-order nonlinear integrating process to characterize the non-self-regulating processes. The approximation to a First Order Integrating System Plus Dead Time is obtained from an experimental method that adopts identification procedures and avoids complex analytical resources. The model contributes to designing the dynamic sliding mode controller and tuning parameters. The resulting controller is a hybrid scheme that combines the sliding mode methodology, a smith predictor structure, and a PD compensator. The hybrid control topology is used for the first time for integrating systems with dead time. The proposed approach is applied to a high order linear integrating system with long-dead time and a coupled tanks system using hardware in the loop (HIL) simulation. The hybrid control topology provides enhanced controller performance, guarantees proven robustness to parameter modeling uncertainties, and attenuates high-frequency oscillations, counteracting the adverse effects of chattering. Integral of Squared Error (ISE), Total Variation of control effort (TVu), Maximum overshoot, and Settling Time are used for quantitative comparative performance analysis.

Published
2022
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40. A Unified Dual Active Bridge Model Based on Improved Extended Describing Function With Dead Time Compensation for Electric Vehicles

Author

Deshu Zhang, Houji Li, and Jie Chen

Subjects
Dual active bridge (DAB), zero voltage switching (ZVS), improved extended describing function, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Dual active bridge (DAB) converter is well suited for deriving a high-power density plug-in hybrid electric vehicle charger. In this case, various DAB operation modes have to be considered, but few papers have established a unified DAB model. Meanwhile, the failure of zero voltage switching (ZVS) operation during the dead time would distort the ideal phase shift angles, deviating the actual DAB state from analysis in previous modeling methods. This article puts forward a substantial effort to address all the above-mentioned hurdles by proposing a unified DAB model with dead time compensation for all operating modes and firstly introducing the improved extended describing function (IEDF) to DAB modeling. Two improvements compared with the traditional functions are implemented: First, due to the high-frequency and non-sinusoidal characteristics of DAB inductor current, the influence of incorporating higher-order harmonics is quantitatively studied, and it is proved that the maximum output voltage error of the IEDF based DAB steady-state model occurs at light load in single phase shift control; Second, the influence of zero voltage switching (ZVS) failure on DAB voltage gain is also studied and the steady- and dynamic-states’ model accuracy of the IEDF based DAB model is greatly improved. Finally, simulations and experiments are carried out with a 2-kW prototype, and the proposed model shows great accuracy in both steady- and dynamic-states characteristics.

Published
2024
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41. Pulse pileup model for spectral resolved X-ray photon-counting detectors with dead time and retrigger capability

Author

P. Zambon and C. Amato

Subjects
counting detector, non-paralyzable, retrigger, dead time, pulse pileup, spectral distortion, Physics, QC1-999
Abstract

We developed an analytical model to evaluate the effect of signal pileup on the recorded energy spectrum in X-ray photon-counting detectors affected by dead time and equipped with retrigger capability. The retrigger function allows the system to work in a specific non-paralyzable counting mode by counting the time-over-threshold of piled-up signals in multiples of a predefined and selectable retrigger time. The model, designed for rectangle-like-shaped signals, allows for arbitrary input energy spectra and can significantly help understand and optimize the behavior of counting detectors with spectral capabilities and retrigger mechanisms in applications involving polychromatic beams, e.g., spectral X-ray imaging and computed tomography (CT), in a time-efficient way. Dedicated numerical simulations were used to validate the model under several conditions of incoming flux and threshold energy, with excellent results.

Published
2023
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43. The matrix optimum filter for Low Temperature Detectors dead-time reduction

Author

Borghesi, Matteo, Faverzani, Marco, Ferrari, Cecilia, Ferri, Elena, Giachero, Andrea, Nucciotti, Angelo, and Origo, Luca

Subjects
Physics - Data Analysis, Statistics and Probability, Physics - Instrumentation and Detectors
Abstract

Experiments aiming at high sensitivities usually demand for a very high statistics in order to reach more precise measurements. However, for those exploiting Low Temperature Detectors (LTDs), a high source activity may represent a drawback, if the events rate becomes comparable with the detector characteristic temporal response. Indeed, since commonly used optimum filtering approaches can only process LTDs signals well isolated in time, a non-negligible part of the recorded experimental data-set is discarded and hence constitute the dead-time. In the presented study we demonstrate that, thanks to the matrix optimum filtering approach, the dead-time of an experiment exploiting LTDs can be strongly reduced.

Published
2022
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46. Experimental study of mutual effects of high carrier frequency, dead-time and control sample time on IPMSM core loss under SiC inverter excitation

Author

Gia Minh Thao Nguyen, Long Ton-That, and Keisuke Fujisaki

Subjects
Motor core loss, SiC inverter, High carrier frequency, Dead-time, Control sample time, Electromagnetic evaluation, Technology
Abstract

This paper experimentally analyzes the core loss characteristics of an interior permanent magnet synchronous motor (IPMSM) excited by a SiC inverter with the sinusoidal pulse-width modulation (PWM) and high modulation index of 1.1 considering the mutual effects of the high carrier frequencies of up to 200 kHz, different dead-times of 250 and 1000 ns, control sample times of 100–1000 μs, and stator core temperature. The experimental IPMSM drive system is operated in load condition with a torque of 1.05 Nm and rotational velocity of 1500 rpm. Furthermore, the ringing phenomenon and rise time in the motor voltage are measured and analyzed using a high-resolution oscilloscope that has a superior sampling rate of up to 5 giga-samples per second (GS/s), which helps to thoroughly examine the impact of the SiC inverter excitation on the motor core loss. The relations of the total harmonic distortion (THD) of the measured motor voltage and current and the distortions in the magnetic flux density through the stator core to the IPMSM core loss properties are also evaluated. Lastly, explanations and insights based on physics of the obtained results are presented.

Published
2023
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48. Fractional-Order Predictive PI Controller-Based Dead-Time Compensator for Wireless Networks

Author

P. Arun Mozhi Devan, Rosdiazli Ibrahim, Madiah Omar, Kishore Bingi, and Hakim Abdulrab

Subjects
wireless networks, dead-time compensation, predictive PI, fractional calculus, process industries, Engineering machinery, tools, and implements, TA213-215
Abstract

Wireless technology is increasingly significant in today’s industrial landscape. Standards like WirelessHART, ZigBee, and ISA100.11a are being widely used. However, despite their widespread use, wireless networks may sometimes be susceptible to packet loss or drops, making closed-loop systems vulnerable and resulting in system failure. To prevent such issues, dead-time compensation is necessary. The conventional techniques of predictive PI are commonly used for this purpose. Still, they must perform optimally for wireless networks with dead time, and set-point variations can affect network stability. To address this, a fractional calculus-based predictive PI compensator is proposed in this paper for wireless networks in process industries to improve the performance of these compensators. Industrial processes that involve wireless measurement and control actions in the pressure process model are used to evaluate the proposed compensator. The wireless network’s performance is assessed for packet loss, reduced throughput, and increased latency, and the proposed compensator outperforms traditional ones to achieve better set-point characteristics.

Published
2023
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49. Analytically derived disturbance rejection‐based PID controller tuning for second‐order plus dead time plants

Author

Saeed Tavakoli and Marzieh Safaei

Subjects
PID control, robust control, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Abstract This letter proposes a proportional‐integral‐derivative (PID) design method for second‐order plus dead time models based on a desired closed‐loop transfer function for load disturbance changes. Also, tuning rules for single integrating first‐order plus dead time models are provided. Using a two‐degree‐of‐freedom control scheme, the design problem considers load disturbance rejection, robustness to model uncertainties, and setpoint tracking. Three examples are used to assess the performance of the proposed method. Finally, the results are compared to two popular PID control design methodologies, skogestad internal model control or skogestad IMC (SIMC) and improved SIMC (iSIMC).

Published
2024
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50. Impact of the dead-time correction method on quantitative 177Lu-SPECT (QSPECT) and dosimetry during radiopharmaceutical therapy

Author

Alessandro Desy, Guillaume F. Bouvet, Nancy Lafrenière, Atefeh Zamanian, Philippe Després, and Jean-Mathieu Beauregard

Subjects
Quantitative imaging, Single-photon emission computed tomography, Dead time, Dosimetry, Lutetium-177, Radiopharmaceutical therapy, Medical physics. Medical radiology. Nuclear medicine, R895-920
Abstract

Abstract Background Dead-time correction is required for accurate quantitative SPECT-based dosimetry in the context of personalised 177Lu radiopharmaceutical therapy. We aimed to evaluate the impact of applying dead-time correction on the reconstructed SPECT image versus on the acquisition projections before reconstruction. Methods Data from 16 SPECT/CT acquisitions of a decaying 177Lu-filled phantom (up to 20.75 GBq) and dual-timepoint SPECT/CT in 14 patients treated with personalised 177Lu peptide receptor radionuclide therapy were analysed. Dead time was determined based on the acquisition wide-spectrum count rate for each projection and averaged for the entire acquisition. Three dead-time correction methods (DTCMs) were used: the per-projection correction, where each projection was individually corrected before reconstruction (DTCM1, the standard of reference), and two per-volume methods using the average dead-time correction factor of the acquisition applied to all projections before reconstruction (DTCM2) or to the SPECT image after reconstruction (DTCM3). Relative differences in quantification were assessed for various volumes of interest (VOIs) on the phantom and patient SPECT images. In patients, the resulting dosimetry estimates for tissues of interest were also compared between DTCMs. Results Both per-volume DTCMs (DTCM2 and DTCM3) were found to be equivalent, with VOI count differences not exceeding 0.8%. When comparing the per-volume post-reconstruction DTCM3 versus the per-projection pre-reconstruction DTCM1, differences in VOI counts and absorbed dose estimates did not exceed 2%, with very few exceptions. The largest absorbed dose deviation was observed for a kidney at 3.5%. Conclusion While per-projection dead-time correction appears ideal for QSPECT, post-reconstruction correction is an acceptable alternative that is more practical to implement in the clinics, and that results in minimal deviations in quantitative accuracy and dosimetry estimates, as compared to the per-projection correction.

Published
2022
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