Parallel Loop Control for Torque and Angular Velocity of BLDC Motors with DTC Commutation

Coballes-Pantoja, J.; Gómez-Fuentes, R.; Noriega, J. R.; García-Delgado, L. A.

doi:10.3390/electronics9020279

Cited by 7 publications

(7 citation statements)

References 17 publications

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“…DFTC is wellknown for its robust strategy, simple algorithm, and fast-flux/torque response, which requires no modulation techniques, current control, or coordinate transformation [44]. This method has been applied to several electric machines such as induction motor [45], a brushless DC electric motor [46], interior permanent magnet synchronous motor [47], five- The stability condition is given by:…”

Section: Dftc-tosmc Control Of the Ag-based Srwpmentioning

confidence: 99%

Improved Rotor Flux and Torque Control Based on the Third-Order Sliding Mode Scheme Applied to the Asynchronous Generator for the Single-Rotor Wind Turbine

Benbouhenni

Bizon

2021

Mathematics

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In this work, a third-order sliding mode controller-based direct flux and torque control (DFTC-TOSMC) for an asynchronous generator (AG) based single-rotor wind turbine (SRWT) is proposed. The traditional direct flux and torque control (DFTC) technology or direct torque control (DTC) with integral proportional (PI) regulator (DFTC-PI) has been widely used in asynchronous generators in recent years due to its higher efficiency compared with the traditional DFTC switching strategy. At the same time, one of its main disadvantages is the significant ripples of magnetic flux and torque that are produced by the classical PI regulator. In order to solve these drawbacks, this work was designed to improve the strategy by removing these regulators. The designed strategy was based on replacing the PI regulators with a TOSMC method that will have the same inputs as these regulators. The numerical simulation was carried out in MATLAB software, and the results obtained can evaluate the effectiveness of the designed strategy relative to the traditional strategy.

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Section: Dftc-tosmc Control Of the Ag-based Srwpmentioning

confidence: 99%

Improved Rotor Flux and Torque Control Based on the Third-Order Sliding Mode Scheme Applied to the Asynchronous Generator for the Single-Rotor Wind Turbine

Benbouhenni

Bizon

2021

Mathematics

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“…Assuming, that the electrical power generated in every winding is changed into mechanical power [35,36], the electromagnetic torque of the motor can be determined by Equation (11):…”

Section: Mathematical Model Of the Bldc Motormentioning

confidence: 99%

Minimization of Torque Ripple in the Brushless DC Motor Using Constrained Cuckoo Search Algorithm

2021

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This paper presents the application of the cuckoo search (CS) algorithm in attempts to the minimization of the commutation torque ripple in the brushless DC motor (BLDC). The optimization algorithm was created based on the cuckoo’s reproductive behavior. The lumped-parameters mathematical model of the BLDC motor was developed. The values of self-inductances, mutual inductances, and back-electromotive force waveforms applied in the mathematical model were calculated by the use of the finite element method. The optimization algorithm was developed in Python 3.8. The CS algorithm was coupled with the static penalty function. During the optimization process, the shape of the voltage supplying the stator windings was determined to minimize the commutation torque ripple. Selected results of computer simulation are presented and discussed.

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“…The mathematical model for a farm vehicle can be established as a rigid body moving in free space of two or three degrees of freedom connected to a flat land surface through the tires (Figure 3). Besides, when considering the estimation of linear and nonlinear dynamics, these can be analyzed in a simplified way with the so-called bicycle model [32,33], resulting in being able to propose a measurement of the variable : ≅̇ is the angular velocity of turn (rad/s), which is in synchrony with [34,35], considering ≠ 0, with ≤ | | > 0, with a minimum value of ( ), for a time t≥ 0 when the sensor SR-PS100 does not detect , and R > 0 is a constant gain which is chosen so that the angular velocity of the turn is not saturated, which relates the input voltage on the actuator with the angular velocity which is obtained from [36]; , are front and rear side slip angles (rad); , are the tire angle components imposed by the driver and controller (rad); ̇= ( − )/ is the angular velocity response of the actuator on the tractor steering wheel (rad/s) and is established as +DDELTAD 1 VOL and +DDELTAD 2 VOL on the PPTD shown in Appendix A, where is the input voltage to actuator (V), > 0 is an estimated back electromotive force constant (V/(rad/s)), is the resistance of the actuator (Ω ), and is the current (A), considering the simplified mathematical model of the cc motor where its values are obtained experimentally; the moment of turn resulting from the active brakes (N m); lateral forces , , , (N) are functions of the angle…”

Section: System Configurationmentioning

confidence: 99%

“…x is the compact state vector; ω z . δ dact R is the angular velocity of turn (rad/s), which is in synchrony with δ d [34,35], considering ω z 0, with ω zmin ≤ |ω z | > 0, with a minimum value of (ω zmin ), for a time t ≥ 0 s when the sensor SR-PS100 does not detect δ d , and R > 0 is a constant gain which is chosen so that the angular velocity of the turn is not saturated, which relates the input voltage on the actuator with the angular velocity which is obtained from [36]; α f , α r are front and rear side slip angles (rad); δ d , δ c are the tire angle components imposed by the driver and controller (rad); imposed on the front tires ( = + ), where and are the angles imposed on the front tire of the driver and controller, respectively; and the lateral slip angles of the tires are defined as follows:…”

Section: Tractor Dynamic Tire Modelsmentioning

confidence: 99%

A Low-Cost Platform for Modeling and Controlling the Yaw Dynamics of an Agricultural Tractor to Gain Autonomy

et al. 2020

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In this study, a low-cost proposed platform for training dynamics (PPTD) is proposed based on operational amplifiers to understand the dynamics and variables of the agricultural tractor John Deere tractor model 4430 to gain autonomy and analyze the behavior of control algorithms proposed in real time by state feedback. The proposed platform uses commercial sensors and interacts with the Arduino Uno and/or Daq-6009 board from National Instruments. A mobile application (APP) was also developed for real-time monitoring of autonomous control signals, the local reference system, and physical and dynamic variables in the tractor; this platform can be used as a mobile alternative applied to a tractor in physically installed form. In the presented case, the PPTD was mounted on a John Deere tractor to test its behavior; moreover, it may be used on other tractor models similarly as established here. The established results of this platform were compared with models established in MATLAB, validating the proposal. All simulations and developments are shared through a web-link as open-source files so that anyone with basic knowledge of electronics and modeling of vehicles can reproduce the proposed platform.

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Parallel Loop Control for Torque and Angular Velocity of BLDC Motors with DTC Commutation

Cited by 7 publications

References 17 publications

Improved Rotor Flux and Torque Control Based on the Third-Order Sliding Mode Scheme Applied to the Asynchronous Generator for the Single-Rotor Wind Turbine

Improved Rotor Flux and Torque Control Based on the Third-Order Sliding Mode Scheme Applied to the Asynchronous Generator for the Single-Rotor Wind Turbine

Minimization of Torque Ripple in the Brushless DC Motor Using Constrained Cuckoo Search Algorithm

A Low-Cost Platform for Modeling and Controlling the Yaw Dynamics of an Agricultural Tractor to Gain Autonomy

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