Your search keyword '"Jamshidpour, Ehsan"' showing total 15 results

1. Optimization of an SSHC-based full active rectifier for piezoelectric energy harvesting

Author

Wassouf, Liana, Jamshidpour, Ehsan, and Frick, Vincent

Published

2023

2. Toward efficient very low frequency wireless power transfer for EVs: From grid to battery.

Author

Bonnard, Charles-Henri, Jamshidpour, Ehsan, Fontchastagner, Julien, Didier, Gaëtan, Zandi, Hamidreza, and Takorabet, Noureddine

Abstract

This paper aims to improve the efficiency, affordability, and safety of Wireless Power Transfer (WPT) devices. While wireless inductive charging is common in devices like smartphones, charging electric vehicles presents significant challenges due to high frequency electromagnetic fields that can be dangerous for users and those nearby. Current systems are expensive due to the use of specialized materials and components. By developing WPT systems with drastically reduced frequency levels, this research has the potential to significantly impact the widespread adoption of affordable, safe, and efficient WPT devices for high-power applications like electric vehicle charging. In fact, using lower frequencies allows us to build WPT systems with far less expensive materials, e.g. no need of Litz wires and ferrites that can be replaced by single core copper wires and classical magnetic steels. The effectiveness of the method is demonstrated through simulation using MATLAB Simulink® and experimental tests. The results indicate that it is possible to maintain good performance, reduce limitations and costs, and improve user acceptance of WPT systems by considerably lowering the frequency of electromagnetic fields that are classically used in such systems. [ABSTRACT FROM AUTHOR]

Published

2024

3. Influence of High-Frequency Operation on the Efficiency of a PMSM Drive with SiC-MOSFET Inverter.

Author

Poolphaka, Paisak, Jamshidpour, Ehsan, Lubin, Thierry, Baghli, Lotfi, and Takorabet, Noureddine

Subjects

*PERMANENT magnets, *COMPUTER simulation

Abstract

This paper investigates the effects of high-frequency switching and a high fundamental frequency on the parameters and efficiency of a high-speed permanent magnet synchronous machine (PMSM) drive. We discuss the design and modeling of the PMSM, taking into account these high-frequency effects. The impact of high frequencies is analyzed across three different inverters (IGBT, Fast IGBT, and SiC-MOSFET) and the motor, and we employ theoretical analysis, computer simulations, and experimental tests for validation. Our goal is to enhance our understanding of how these high-frequency factors affect the performance of the motor drive. [ABSTRACT FROM AUTHOR]

Published

2024

4. Comparative Study of IGBT and SiC MOSFET Three-Phase Inverter: Impact of Parasitic Capacitance on the Output Voltage Distortion.

Author

Poolphaka, Paisak, Jamshidpour, Ehsan, Lubin, Thierry, Baghli, Lotfi, and Takorabet, Noureddine

Subjects

ELECTRIC capacity, VOLTAGE, PULSE width modulation transformers, COMPARATIVE studies

Abstract

This study investigates the nonlinearities in three-phase inverters for SiC-based systems and compares their performance to IGBT-based systems. An analytical model of inverter voltage distortion is developed, which accounts not only for dead time (td), switching delay time, switching frequency (fs), and voltage drops of power devices, but also for output parasitic capacitance (Cout). Experimental tests validate the model, which provides a more accurate estimate of the inverter's output phase voltage distortion. The power device characteristics are obtained from datasheets, while Cout is determined through experimentation. Three-phase inverters with varying switching frequencies, fundamental frequencies, and dead-time values are used in simulations and experiments to determine the influence of nonlinearity on phase voltage deviation and current distortion. The results show that, due to SiC devices' faster switching time, the phase voltage deviation and phase current distortion are lower in SiC-based inverters than in IGBT-based ones for high-frequency applications, as the dead time can be reduced. [ABSTRACT FROM AUTHOR]

Published

2023

5. A Parameter-Free Method for Estimating the Stator Resistance of a Wound Rotor Synchronous Machine.

Author

Haghgooei, Peyman, Jamshidpour, Ehsan, Corne, Adrien, Takorabet, Noureddine, Khaburi, Davood Arab, Baghli, Lotfi, and Nahid-Mobarakeh, Babak

Subjects

MACHINE performance, KALMAN filtering, ROTORS, MACHINERY, PARAMETER identification, WOUNDS & injuries

Abstract

This paper presents a new online method based on low frequency signal injection to estimate the stator resistance of a Wound Rotor Synchronous Machine (WRSM). The proposed estimator provides a parameter-free method for estimating the stator resistance, in which there is no need to know the values of the parameters of the machine model, such as the stator and rotor inductances or the rotor flux linkage. In this method, a low frequency sinusoidal current is injected in the d axis of the stator current to produce a sinusoidal flux in the stator. In this paper, it is shown that the phase difference between the generated sinusoidal flux and the injected sinusoidal current is related to the stator resistance mismatch. Using this phase difference, the stator resistance is estimated. To validate the proposed model-free estimator, simulations were performed with Matlab Simulink and the results were compared with the extended Kalman filter observer. Finally, experimental tests, under different conditions, were performed to estimate the stator resistance of a WRSM. [ABSTRACT FROM AUTHOR]

Published

2023

6. High Gain PWM Method and Active Switched Boost Z-Source Inverter With Less Voltage Stress on the Devices.

Author

Abbasi, Milad, Mardaneh, Mohammad, and Jamshidpour, Ehsan

Subjects

PULSE width modulation transformers, VOLTAGE, PASSIVE components, PULSE width modulation, DC-AC converters, ELECTROSTATIC induction

Abstract

This article presents a new circuit topology for high voltage gain active switched boost quasi Z-source inverter (qZSI) and a pulsewidth modulation (PWM) technique. The higher boosting capability with a lower number of elements, the continuous source current, the less voltage stress across the devices, and having the common ground are the main advantages of the proposed structure. The voltage gain of the proposed inverter is twice that of the conventional capacitor-assisted qZSI (sCA-qZSI). Other benefits of the proposed inverter over the sCA-qZSI are the reduction of Z-source passive components and shoot-through current. Compared to the conventional active switched inductor boost qZSI, the proposed inverter has higher output voltage and also lower shoot-through current, while it has fewer components (one fewer inductor, two fewer diodes, but one more capacitor). The boost factor of the proposed inverter is more than twice that of the classic ones. Besides, a high gain PWM technique is proposed, which can be applied to any types of Z-source inverters. Both the simulation and experimental results of the proposed inverter under the proposed PWM technique are examined to validate their operation. [ABSTRACT FROM AUTHOR]

Published

2022

7. Photovoltaic Systems Reliability Improvement by Real-Time FPGA-Based Switch Failure Diagnosis and Fault-Tolerant DC–DC Converter.

Author

Jamshidpour, Ehsan, Poure, Philippe, and Saadate, Shahrokh

Subjects

*PHOTOVOLTAIC power systems, *PENETRATION mechanics, *MECHANICAL loads, *FAULT tolerance (Engineering), *FIELD programmable gate arrays, *TELECOMMUNICATION

Abstract

The increased penetration of photovoltaic (PV) systems in different applications with critical loads such as in medical applications, industrial control systems, and telecommunications has highlighted pressing needs to address reliability and service continuity. Recently, distributed maximum power point tracking architectures, based on dc–dc converters, are being used increasingly in PV systems. Nevertheless, dc–dc converters are one of the important failure sources in a PV system. Since the semiconductor switches are one of the most critical elements in these converters, a fast switch fault detection method (FDM) is a mandatory step to guarantee the service continuity of these systems. This paper proposes a very fast FDM based on the shape of the inductor current associated to fault-tolerant (FT) operation for boost converter used in PV systems. By implementing fault diagnosis and reconfiguration strategies on a single field-programmable gate array target, both types of switch failure (open- and short-circuit faults) can be detected, identified and handled in real time. The FDM uses the signal provided by the current sensor dedicated to the control of the system. Consequently, no additional sensor is required. The proposed FT topology is based on a redundant switch. The results of hardware-in-the-loop and experimental tests, which all confirm the excellent performances of the proposed approach, are presented and discussed. The obtained results show that a switch fault can be detected in less than one switching period, typically around 100 ms in medium power applications, by the proposed FDM. [ABSTRACT FROM PUBLISHER]

Published

2015

8. Single-Switch DC-DC Converter With Fault-Tolerant Capability Under Open- and Short-Circuit Switch Failures.

Author

Jamshidpour, Ehsan, Poure, Philippe, Gholipour, Eskandar, and Saadate, Shahrokh

Subjects

*DC-to-DC converters, *SHORT-circuit currents, *ELECTRIC switchgear, *FAULT-tolerant control systems, *POWER electronics, *RELIABILITY in engineering

Abstract

This paper proposes fault-tolerant (FT) operation of a single-switch dc-dc converter under a switch failure. In order to improve the reliability in critical applications, FT operation is mandatory to guarantee service continuity. The FT operation of a power system can be performed in three steps: fault diagnosis (detection and identification) and remedial actions. In the case of a switch failure, suitable fault detection is essential to avoid its propagation to the whole system. This study is based on a fast and efficient open- and short-circuit switch fault diagnosis. Both types of switch failure can be detected, identified, and handled in real time by implementing fault diagnosis and reconfiguration strategies on a field-programmable gate array target. No additional sensor is required to perform the fault detection. A redundant switch and a bidirectional switch are needed for converter reconfiguration in postfault operation. The results of hardware-in-the-loop and experimental tests, which all confirm the good performances of the proposed approach, are presented and discussed. [ABSTRACT FROM AUTHOR]

Published

2015

9. Correction: Frick et al. Voltage Flip Efficiency Enhancement for Piezo Energy Harvesting. Electronics 2021, 10 , 2400.

Author

Frick, Vincent, Wassouf, Liana, and Jamshidpour, Ehsan

Subjects

ENERGY harvesting, VOLTAGE, FLIP chip technology

Abstract

Reference 1 Frick V., Wassouf L., Jamshidpour E. Voltage Flip Efficiency Enhancement for Piezo Energy Harvesting. Voltage Flip Efficiency Enhancement for Piezo Energy Harvesting. The red/diamond curve corresponds to signal "FAR" and the blue/o curve corresponds to "Switch Only". [Extracted from the article]

Published

2022

10. Open- and Short-Circuit Switch Fault Diagnosis for Nonisolated DC–DC Converters Using Field Programmable Gate Array.

Author

Shahbazi, Mahmoud, Jamshidpour, Ehsan, Poure, Philippe, Saadate, Shahrokh, and Zolghadri, Mohammad Reza

Subjects

*CONVERTERS (Electronics), *PROTOCOL converters, *SWITCHING power supplies, *DIGITAL control systems, *POWER semiconductors

Abstract

Fault detection (FD) in power electronic converters is necessary in embedded and safety critical applications to prevent further damage. Fast FD is a mandatory step in order to make a suitable response to a fault in one of the semiconductor devices. The aim of this study is to present a fast yet robust method for fault diagnosis in nonisolated dc–dc converters. FD is based on time and current criteria which observe the slope of the inductor current over the time. It is realized by using a hybrid structure via coordinated operation of two FD subsystems that work in parallel. No additional sensors, which increase system cost and reduce reliability, are required for this detection method. For validation, computer simulations are first carried out. The proposed detection scheme is validated on a boost converter. Effects of input disturbances and the closed-loop control are also considered. In the experimental setup, a field programmable gate array digital target is used for the implementation of the proposed method, to perform a very fast switch FD. Results show that, with the presented method, FD is robust and can be done in a few microseconds. [ABSTRACT FROM PUBLISHER]

Published

2013

11. Distributed Active Resonance Suppression in Hybrid DC Power Systems Under Unbalanced Load Conditions.

Author

Jamshidpour, Ehsan, Nahid-Mobarakeh, Babak, Poure, Philippe, Pierfederici, Serge, Meibody-Tabar, Farid, and Saadate, Shahrokh

Subjects

*RESONANCE, *HYBRID power systems, *DIRECT current in electric power distribution, *ELECTRICAL load, *POWER electronics, *ELECTRIC impedance, *CAPACITORS

Abstract

Power-electronics-based hybrid dc power systems (HDCPSs) are increasingly used in many industrial applications such as land, sea, and air vehicles. In these systems, small dc-link and LC filter capacitors are of great interest for weight saving. Usually, in HDCPSs, there are constant power loads and negative dynamic impedance of these loads may generate unstable oscillations. Besides, the risk of resonance may be increased under unbalanced load conditions. In this paper, a distributed active oscillation suppression approach is presented. It is based on the analytical study of the linearized model of the studied system around the operating point. The studied system consists of one main dc source and one storage element supplying two loads: a permanent magnet synchronous motor connected to the dc link by a voltage source inverter and a resistive load supplied by a dc/dc converter through the same dc bus. The proposed approach is particularly used to overcome the resonance under unbalanced load conditions and allows reducing dc link and LC filter capacitors for weight saving. Simulations and experimentations are carried out which confirm the validity of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2013

12. Voltage Flip Efficiency Enhancement for Piezo Energy Harvesting.

Author

Frick, Vincent, Wassouf, Liana, and Jamshidpour, Ehsan

Subjects

ENERGY harvesting, FLIP chip technology, OPEN-circuit voltage, VOLTAGE, COMPLEMENTARY metal oxide semiconductors, INTEGRATED circuits, PIEZOELECTRIC transducers, CAPACITORS

Abstract

In this paper, we analyze the effect of an enhanced voltage flip technique on the power performance of a piezoelectric energy harvester. The enhanced voltage flip principle is based on a synchronized-switch-based architecture, and is referred to as FAR (Full Active Rectifier). It uses a tiny amount of the stored charge to boost the voltage flip. This work aims to demonstrate that, beside the enhanced flip efficiency, the FAR also contributes to improve the power efficiency of the harvester, especially under changing load constraint. Therefore, the paper proposes a thorough comparison between the FAR and its conventional counterpart, the Switch-only technique. The FAR is easy to implement and does not require any external inductor or capacitor. It only needs a reduced set of switches, an active diode and a simple control sequence, and can thus be implemented on a fully integrated circuit. The FAR can be used as a standalone voltage flip solution or in addition to further boost the flip efficiency in a state-of-the-art architecture such as SSHC for example. Tests were performed on a 0.35-µm process CMOS prototype IC. Experimental results revealed that the FAR extracts 19.1 μ W from an off-the-shelf piezoelectric transducer when the output voltage is regulated at 1 V with 1 V open-circuit voltage and delivers up to 20% more power than the conventional Switch-only technique under load constraint. It also shows over 11 × power efficiency improvement compared to a conventional diode-based full bridge rectifier. [ABSTRACT FROM AUTHOR]

Published

2021

13. Equivalent Two Switches and Single Switch Buck/Buck-Boost Circuits for Solar Energy Harvesting Systems.

Author

Jamshidpour, Ehsan, Jovanovic, Slavisa, and Poure, Philippe

Subjects

*ENERGY harvesting, *SWITCHING circuits, *CASCADE converters, *SOLAR energy, *ROTARY converters, *VOLTAGE control

Abstract

In this paper, a comparative analysis has been presented of two equivalent circuits of non-isolated buck/buck-boost converters under synchronous control, used in a stand-alone Photovoltaic-battery-load system. The first circuit consists of two cascaded buck and buck-boost classical converters with two controllable switches. The buck converter is used to extract the maximum power of the Photovoltaic source, and the buck-boost converter is applied for the output voltage level control. The second circuit consists of a proposed converter with a single controllable switch. In both cases, the switching frequency is used to track the maximum power point and the duty ratio controls the output voltage level. Selected simulation results and experimental tests confirm that the two conversion circuits have identical behavior under synchronous control. This study shows that the single switch converter has a lower size and cost, but it is limited in the possible control strategy. [ABSTRACT FROM AUTHOR]

Published

2020

14. Modulation Strategy with a Minimal Number of Commutations for a Five-Level H-Bridge NPC Inverter.

Author

Becker, Florent, Jamshidpour, Ehsan, Poure, Philippe, and Saadate, Shahrokh

Subjects

ELECTRIC potential

Abstract

In this paper, a so-called OPTimized Pulse Width Modulation (OPT-PWM) strategy with a minimal number of commutations for a multilevel converter (MC) is proposed. The principle is based on the reduction of the number of switch commutations by removing the unnecessary ones for each voltage level transition. The OPT-PWM strategy is applied to a five-level H-Bridge Neutral Point Clamped (HB-5L-NPC) inverter. A specific block based on a state machine is added to conventional modulation techniques to perform the transitions from a given voltage level to another one via the best trajectory with a minimal number of commutations. The principle of this additional block can be applied to any modulation technique. In this paper, the proposed strategy is validated first by simulation and then through experimental tests. [ABSTRACT FROM AUTHOR]

Published

2019

15. Common Switch Fault Diagnosis for Two-Stage DC-DC Converters Used in Energy Harvesting Applications.

Author

Jamshidpour, Ehsan, Poure, Philippe, and Saadate, Shahrokh

Subjects

FAULT diagnosis, ENERGY harvesting, ROTARY converters, HARDWARE-in-the-loop simulation, SHORT circuits, HARVESTING

Abstract

This paper proposes a new Unified Switch Fault Diagnosis (UFD) approach for two-stage non-isolated DC-DC converters used in energy harvesting applications. The proposed UFD is compared with a switch fault diagnosis consisting of two separate fault detection algorithms, working in parallel for each converter. The proposed UFD is simpler than the two parallel fault diagnosis methods in realization. Moreover, it can detect both types of switch failures, open circuit and short circuit switch faults. It can also be used for any two-stage non-isolated DC-DC converters based on two single switch converters, no matter the converter circuits in each stage. Some selected simulation and Hardware-in-the-Loop (HIL) experimentation results confirm the validity and efficiency of the proposed UFD. Also, the proposed UFD is applied successfully for fault-tolerant operation of a buck/buck–boost two-stage converter with synchronous control and a redundant switch. [ABSTRACT FROM AUTHOR]

Published

2019