Cost function‐based modulation scheme of model predictive control for VIENNA rectifier

Dang, Chaoliang; Tong, Xiangqian; Song, Weizhang; Han, Yi; Wheeler, Pat

doi:10.1049/iet-pel.2019.0546

Cited by 22 publications

(18 citation statements)

References 32 publications

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“…However, the current ripple is relatively large because the optimal voltage vector is applied during the whole sampling period. Aiming to reduce the current ripple and improve the steady-state performance of the FCS-MPC method without increasing the sampling frequency, some multi-vector MPC strategies have been reported [23][24][25][26][27]. A discrete space vector modulation MPC method is presented in [23].…”

Section: Introductionmentioning

confidence: 99%

“…Given that only two real voltage vectors are utilized to synthesize the virtual voltage vectors for the grid current control, the steady-state performance is still not satisfactory. To further enhance the steady-state performance, three or four voltage vectors are applied in every sampling period in [24][25][26][27]. In [24], three real voltage vectors are utilized to synthesize the virtual voltage vectors.…”

Section: Introductionmentioning

confidence: 99%

“…In [24], three real voltage vectors are utilized to synthesize the virtual voltage vectors. In [25], four voltage vectors are selected based on the location of the grid voltage vector, and the duty cycles for different voltage vectors are set according to the values of their cost functions. In [26], three voltage vectors are selected by pre-selecting one redundant vector, and their duty cycles are obtained by minimizing the cost function using a least-square optimization method.…”

Section: Introductionmentioning

confidence: 99%

“…To reduce the computational burden of the method in [26], the equivalence relation between different switching sequences is derived, and a computationally efficient optimal switching sequence model predictive control (CE-OSS-MPC) is proposed in [27]. However, these methods [24][25][26][27] are directly optimizing the switching sequences. Thus, they require to store the switching states of all the voltage vectors, which increases the memory usage.…”

Section: Introductionmentioning

confidence: 99%

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Model predictive duty cycle control for three‐phase Vienna rectifiers

Liu

Ran

et al. 2022

IET Power Electronics

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The Vienna rectifiers are widely used in industrial applications. The computationally efficient optimal switching sequence model predictive control directly optimizes the switching sequences. Thus, it requires to store the switching states of 25 voltage vectors, which increases the memory usage. Moreover, the neutral-point (NP) voltage is regulated by redundant vector preselection. As only one redundant vector is applied during the whole sampling period, the NP voltage ripple is relatively large, and the grid current performance is still not satisfactory. To overcome these drawbacks, this paper proposes a model predictive duty cycle control strategy for three-phase Vienna rectifiers, which directly optimizes three-phase duty cycles. The three-phase duty cycles are first obtained by predicting the effects of three-phase duty cycles on instantaneous current variations and minimizing a cost function. To guarantee the grid current performance, a novel three-phase duty cycles modification method is proposed by considering the structural characteristics of the Vienna rectifier. To suppress the NP voltage ripple, the obtained three-phase duty cycles are further optimized. With the proposed method, low memory usage, low harmonic distortion in the grid current, and low NP voltage ripple are achieved simultaneously. Experiments are conducted to verify the effectiveness of the proposed method.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Model predictive duty cycle control for three‐phase Vienna rectifiers

Liu

Ran

et al. 2022

IET Power Electronics

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“…In [15], the direct torque control for Vienna rectifier considers not only the torque and flux, but also the neutral-point voltage and then the optimized voltage vector generates by the lookup table. In [16], a cost function based model predictive control modulation scheme is proposed. It can output three voltage vectors in each switching cycle, which effectively reduces the grid current total harmonic distortion (THD) and achieve a fixed switching frequency.…”

Section: Introductionmentioning

confidence: 99%

Model predictive direct power control scheme for Vienna rectifier with constant switching frequency

Dang

Wang

Liu

et al. 2021

IET Power Electronics

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Model predictive direct power control (MPDPC) has strong robustness and fast dynamic response, so it is widely applied in the control system of grid-connected converter. However, the traditional FCS-MPC bears with variable switching state, which will reduce the current tracking accuracy, accidentally produce current ripple and electromagnetic noise.Here, a double closed-loop control strategy with constant switching frequency based on optimal switching sequence synthesis of model predictive direct power control (MPDPC-CF) in the inner loop and SMC control in the outer loop is proposed for the non-linear system of Vienna rectifier. Firstly, the Vienna rectifier is modelled to obtain the predicted values of input power. Then, the given values of active power and reactive power are obtained through the outer loop. Three adjacent voltage vectors with the lowest cost function in the sector are selected to synthesize the optimal voltage vector, and the pulse time of the corresponding vector is calculated according to the cost function of the voltage vector. To verify the correctness of the theoretical analysis, the Vienna rectifier is taken as the research object, and the comparison with the traditional MPDPC shows that the proposed constant frequency model predictive control has good steadystate and dynamic performance.

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A novel low‐complexity model predictive control for Vienna rectifier

Sun

Jin

et al. 2023

Circuit Theory & Apps

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SummaryA Vienna rectifier is a kind of three‐phase converter with complex operation constraints. Traditional control methods suffer from poor dynamic responses and total harmonic distortion (THD), particularly when operating with adjustable wide‐range power. A novel low‐complexity model predictive control (LC‐MPC) algorithm is proposed based on the optimal switching vector sequence in this paper. First, a model predictive optimization control (MPOC) method is designed to search for the voltage vector sequence and its acting time. Second, the equivalent transformation and coordinate mapping of MPOC are efficiently achieved through the derived correlation factors and lookup table. Supported by the correlation factors, the redundant objective function calculation and repetitive online optimization are eliminated. Meanwhile, the simplified optimal over‐modulation strategy is implemented. Finally, the effectiveness and superiority of the algorithm are verified by comparative experiments. The results show that the proposed LC‐MPC is beneficial in terms of the computation time, dynamic response, over‐modulation, and harmonic content reduction.

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Cost function‐based modulation scheme of model predictive control for VIENNA rectifier

Cited by 22 publications

References 32 publications

Model predictive duty cycle control for three‐phase Vienna rectifiers

Model predictive duty cycle control for three‐phase Vienna rectifiers

Model predictive direct power control scheme for Vienna rectifier with constant switching frequency

A novel low‐complexity model predictive control for Vienna rectifier

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