Hardware in the Loop Real-time Simulation for the Associated Discrete Circuit Modeling Optimization Method of Power Converters

Guo, Xiaojun; Yuan, Jiaqi; Tang, Yiguo; You, Xiaojie

doi:10.3390/en11113237

Cited by 9 publications

(9 citation statements)

References 29 publications

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“…[28][29][30]. More recently, HLS has also been used for custom implementations of HS for HIL [26,31] and for its testbenches. The use of HLS for HIL has been shown to impose limitations on hardware performance and resource utilization when intended to be used in HS for HIL [11].…”

Section: Hardware Description Languagesmentioning

confidence: 99%

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A Latency-Insensitive Design Approach to Programmable FPGA-Based Real-Time Simulators

2020

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This paper presents a methodology for the design of field-programmable gate array (FPGA)-based real-time simulators (RTSs) for power electronic circuits (PECs). The programmability of the simulator results from the use of an efficient and scalable overlay architecture (OA). The proposed OA relies on a latency-insensitive design (LID) paradigm. LID consists of connecting small processing units that automatically synchronize and exchange data when appropriate. The use of such data-driven architecture aims to ease the design process while achieving a higher computational efficiency. The benefits of the proposed approach is evaluated by assessing the performance of the proposed solver in the simulation of a two-stage AC–AC power converter. The minimum achievable time-step and FPGA resource consumption for a wide range of power converter sizes is also evaluated. The proposed overlays are parametrizable in size, they are cost-effective, they provide sub-microsecond time-steps, and they offer a high computational performance with a reported peak performance of 300 GFLOPS.

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Section: Hardware Description Languagesmentioning

confidence: 99%

“…The circuit has been modelled using the ADC model. As previously discussed, the ADC is known to introduced fictitious oscillations and the conductance needs to be tuned [31]. The tuning was performed using the 2-norm relative error of the load currents [53]:…”

Section: Open-loop Test Casementioning

confidence: 99%

A Latency-Insensitive Design Approach to Programmable FPGA-Based Real-Time Simulators

2020

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“…Traditional CPU-based HIL simulators, where the time step is usually in 40-100 μs range, can hardly take into accounts the entire switching event from pulse width modulation (PWM) in modern power electronics systems, so the multiple switching events within one fixed simulation time step h may produce erroneous simulation results [4][5][6][7]. The high parallelism provided by field-programmable gate array (FPGA) can compute the real-time simulation model from microsecond to nanosecond range, which is suitable for PEC with high-switching frequency [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

FPGA‐based hardware‐in‐the‐loop real‐time simulation implementation for high‐speed train electrical traction system

Guo

Tang

et al. 2020

IET Electric Power Applications

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The hardware-in-the-loop (HIL) real-time simulation for high-speed train electrical traction system aims to reduce the design cost and speed up control verification process of algorithms in the developmental stage of the traction control unit. In this study, based on the dSPACE real-time simulator, the multiple-simulator, multiple-simulation step of HIL real-time simulation system is first built. Second, for the associated discrete circuit modelling method, an optimisation method is proposed to minimise the switching loss and improve the simulation accuracy by selecting the optimal discrete-time switch admittance parameter, G S. To decrease the computational burden for field-programmable gate array (FPGA), a decoupling method without simulation latency is presented to reduce the matrix dimension of the system model. Finally, the real-time simulation models of electrical traction system are realised by CPU + FPGA-based simulator, in which the power electronics converter models are computed in FPGA with a fixed 100 ns time-step. The validity and reliability of the real-time simulation system is verified by the HIL simulation and experimental results, which indicate that the real-time HIL simulation at the nanosecond level improves the accuracy essentially.

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“…Switched mode DC-DC power converters [1], are mainly used as constant current sources for LEDs, industry lighting, mobile phones, and photovoltaic systems [2,3]. Among the well known DC-DC converter topologies as buck, boost, buck-boost and cúk converters, the last three mentioned topologies result in being nonminimum-phase when directly controlling the output capacitor voltage variable [4].…”

Section: Introductionmentioning

confidence: 99%

Sliding Mode Output Regulation for a Boost Power Converter

Rivera

Ortega-Cisneros

Chavira³

2019

Energies

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This work deals with the novel application of the sliding mode (discontinuous) output regulation theory to a nonlinear electrical circuit, the so-called boost power converter. This theory has excelled due to the fact that trajectory tracking plays a central role. The control of a boost power converter for the output tracking of a DC biased sinusoidal signal is a challenging problem for control engineers. The main difficulties are the computation of a proper reference signal for the inductor current, and the stabilization of the inductor current dynamics or to guarantee the correct output tracking of the capacitor voltage. With the application of the discontinuous output regulation these problems are solved in this work. Simulations and real time experiments were carried out with an unknown variation of the DC input voltage, where the good output tracking of the capacitor voltage was verified along with the stabilization of the inductor current. The discontinuous output regulation theory has proven to be a suitable tool in the output tracking for the boost power converter.

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Hardware in the Loop Real-time Simulation for the Associated Discrete Circuit Modeling Optimization Method of Power Converters

Cited by 9 publications

References 29 publications

A Latency-Insensitive Design Approach to Programmable FPGA-Based Real-Time Simulators

A Latency-Insensitive Design Approach to Programmable FPGA-Based Real-Time Simulators

FPGA‐based hardware‐in‐the‐loop real‐time simulation implementation for high‐speed train electrical traction system

Sliding Mode Output Regulation for a Boost Power Converter

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