Model, design and implementation of a low‐cost HIL for power converter and microgrid emulation using DSP

Bastos, Rogério Cid; Fuzato, Guilherme Henrique Favaro; Aguiar, Cassius Rossi de; Neves, Rodolpho Vilela Alves; Machado, Ricardo Q.

doi:10.1049/iet-pel.2019.0302

Cited by 9 publications

(7 citation statements)

References 11 publications

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“…However, it is nearly impossible to use microprocessors for high-frequency power converters in RT because of the small needed simulation step. For instance, a digital signal processor (DSP)-based HIL system for power converters such as Boost converter with a time step of 1 µs was proposed in [14]. Using the rule of 100 simulation steps per switching period, that would limit the switching period to a minimum of 100 µs and therefore switching frequencies under 10 kHz.…”

Section: Hil Modelmentioning

confidence: 99%

Comparison of Different Design Alternatives for Hardware-in-the-Loop of Power Converters

et al. 2021

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This paper aims to compare different design alternatives of hardware-in-the-loop (HIL) for emulating power converters in Field Programmable Gate Arrays (FPGAs). It proposes various numerical formats (fixed and floating-point) and different approaches (pure VHSIC Hardware Description Language (VHDL), Intellectual Properties (IPs), automated MATLAB HDL code, and High-Level Synthesis (HLS)) to design power converters. Although the proposed models are simple power electronics HIL systems, the idea can be extended to any HIL system. This study compares the design effort of different coding methods and numerical formats considering possible synthesis tools (Precision and Vivado), and it comprises an analytical discussion in terms of area and speed. The different models are synthesized as ad-hoc modules in general-purpose FPGAs, but also using the NI myRIO device as an example of a commercial tool capable of implementing HIL models. The comparison confirms that the optimum design alternative must be chosen based on the application (complexity, frequency, etc.) and designers’ constraints, such as available area, coding expertise, and design effort.

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Section: Hil Modelmentioning

confidence: 99%

Comparison of Different Design Alternatives for Hardware-in-the-Loop of Power Converters

et al. 2021

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“…The same platform is used to test HIL of a boost converter and a full-bridge in power electronics applications [19]. Furthermore, a HIL implementation using a DSP LaunchPad C2000 Delfino F28377S is presented for microgrids applications in [20]. Three different converters are modelled in this study to validate the capabilities of the proposed DSP based HIL platform.…”

Section: Introductionmentioning

confidence: 99%

“…Besides, it is challenging to carry out a precise comparison of them, because most of the low-cost platforms are not commercially available and they are case a case implemented by research groups, tailored to a particular application. However, using the comparison reported in [20], it is concluded that the control systems implemented utilising some DSP platforms, can achieve time steps as low as 860 ns, higher than that achievable with the (relatively high cost) Typhoon system (≈560 ns) but still good enough to represent IGBTs in some typical application, for instance, microgrids, where the power converter switching frequency is about 10 kHz. As discussed in [8], the implementations based on FPGAs are also relatively low-cost alternatives for HIL and RTCP, achieving applications with low time steps.…”

Section: Introductionmentioning

confidence: 99%

Design and Implementation of a Low-Cost Real-Time Control Platform for Power Electronics Applications

et al. 2020

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In recent years, different off-the-shelf solutions for the rapid control prototyping of power electronics converters have been commercialised. The main benefits of those systems are based on a fast and easy-to-use environment due to high-level programming. However, most of those systems are very expensive and are closed software and hardware solutions. In this context, this paper presents the design and implementation of a control platform targeting at the segment in between expensive off-the-shelf control platforms and low-cost controllers. The control platform is based on the Launchpad TMS320F28379D from Texas Instruments, and it is equipped with an expansion board that provide analogue-to-digital measurements, switching signals and hardware protections. The performance of the control platform is experimentally tested on a 20 kVA power converter.

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“…However, in a recent paper [1], the authors have shown that it is possible to achieve

T_{s} \approx 1 μ s

for RT simulation of a power converter using the new generation of DSP processor. Slower than the FPGA approach, however easier to program, due to the high‐level language (C + +), with very low implementation cost, free software and friendlier environment for all engineering community.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, a digital model interfaced with real controllers and actuators running in RT can reduce cost and time for testing ideas. In addition, it provides the security of not working with real variables like high voltages, high current, high speeds etc [1].…”

Section: Introductionmentioning

confidence: 99%

Low‐cost hardware‐in‐the‐loop for real‐time simulation of electric machines and electric drive

Bastos

Silva

Aguiar

et al. 2020

IET Electric Power Applications

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This study aims to present the discrete models and the methodology to implement real‐time simulations of electric machines using a low‐cost digital signal processor (DSP). The DC machine and the three‐phase induction machine are modelled in real‐time using a Texas Instruments DSP TMS28379D, where the discrete models are implemented using C language. A minimum time‐step of 1 µs can be achieved for the DC machine and 1.5 µs for the inductions machine in the experimental hardware. To validate the described models and show their precision, they are compared with commercial computational models from PSIM®. In addition, closed‐loop speed control strategies are applied to the real‐time DSP experimental models, showing perfect concordance with the machine theory. For the DC machine, a speed control strategy with an inner current control loop is applied and for the induction machine, a field‐oriented control for the speed control. The proposed real‐time simulation hardware has a great potential for low‐budget research and educational purposes since it can replace a real machine setup for a very low price, with great accuracy, variable parameters and free from risks, such as accidents or equipment damage. Furthermore, it uses cheap hardware with free software and a high‐level programing language.

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Model, design and implementation of a low‐cost HIL for power converter and microgrid emulation using DSP

Cited by 9 publications

References 11 publications

Comparison of Different Design Alternatives for Hardware-in-the-Loop of Power Converters

Comparison of Different Design Alternatives for Hardware-in-the-Loop of Power Converters

Design and Implementation of a Low-Cost Real-Time Control Platform for Power Electronics Applications

Low‐cost hardware‐in‐the‐loop for real‐time simulation of electric machines and electric drive

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