Regenerative Intelligent Brake Control for Electric Motorcycles

Aguilar, Juan Jesús Castillo; Fernández, Javier Pérez; García, Juan M. Velasco; Carrillo, Juan Antonio Cabrera

doi:10.3390/en10101648

Cited by 8 publications

(8 citation statements)

References 17 publications

(20 reference statements)

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“…Husain [52] 2018 Fuzzy expert system transformers via dissolved gas analysis test S.; Sedraoui Kahla, el al. [53] 2018 Combination of standard onoff strategy with fuzzy logic Maximize the power point tracking of wind energy Aguilar [49] used a simple fuzzy logic algorithm for the intelligent brake control of an electric motorcycles engine in order to recover the maximum energy in braking processes while maintaining the vehicle's stability. The success of the employed method is very bold, such that the results of comparing the regenerative system with the ABS in a low adhesion condition have been presented in Figure 9 in terms of mean deceleration (a) and distance (b).…”

Section: Simple Fuzzy Systemsmentioning

confidence: 99%

“…(a) (b) Figure 9. results of the study by Aguilar [49] in terms of (a) mean deceleration and (b) distance.…”

Section: Simple Fuzzy Systemsmentioning

confidence: 99%

“…Such composed system is called fuzzy neural, neural fuzzy, neuro-fuzzy or fuzzy-neuro network, or ANFIS in which Figure 9. Results of the study by Aguilar [49] in terms of (a) mean deceleration and (b) distance.…”

Section: Anfis: Neuro-fuzzymentioning

confidence: 99%

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Review of Soft Computing Models in Design and Control of Rotating Electrical Machines

et al. 2019

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Rotating electrical machines are electromechanical energy converters with a fundamental impact on the production and conversion of energy. Novelty and advancement in the control and high-performance design of these machines are of interest in energy management. Soft computing methods are known as the essential tools that significantly improve the performance of rotating electrical machines in both aspects of control and design. From this perspective, a wide range of energy conversion systems such as generators, high-performance electric engines, and electric vehicles, are highly reliant on the advancement of soft computing techniques used in rotating electrical machines. This article presents the-state-of-the-art of soft computing techniques and their applications, which have greatly influenced the progression of this significant realm of energy. Through a novel taxonomy of systems and applications, the most critical advancements in the field are reviewed for providing an insight into the future of control and design of rotating electrical machines.

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Section: Simple Fuzzy Systemsmentioning

confidence: 99%

“…(a) (b) Figure 9. results of the study by Aguilar [49] in terms of (a) mean deceleration and (b) distance.…”

Section: Simple Fuzzy Systemsmentioning

confidence: 99%

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Review of Soft Computing Models in Design and Control of Rotating Electrical Machines

et al. 2019

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“…The measurement of the vertical force (F z ) applied to the tire by the external force of the swingarm is calculated by measuring the deformation of the tire. Finally, to model the electrical system, the motor map provided by the manufacturer is used as well as a model of the power inverter (see [30]). As can be seen, the power inverter output is modelled as a second order system, Equation (9), where s is the throttle percentage; normalf(s) = 10.007 s2 + 0.134 s + 1 .…”

Section: Controllermentioning

confidence: 99%

“…Therefore, a controller based on fuzzy logic, which is widely known for its robustness and widespread use in control systems in vehicles, was programmed. Since the development of this algorithm was not the main objective of this work, a controller previously developed by our research group [30] was used. The Simulink ® model optimizes the parameters for the specific task.…”

Section: Controllermentioning

confidence: 99%

Low-Cost FPGA-Based Electronic Control Unit for Vehicle Control Systems

Fernández

Vargas

García

et al. 2019

Sensors

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The development of new control algorithms in vehicles requires high economic resources, mainly due to the use of generic real-time instrumentation and control systems. In this work, we proposed a low-cost electronic control unit (ECU) that could be used for both development and implementation. The proposed electronic system used a hybrid system on chip (SoC) between a field-programmable gate array (FPGA) and an Advanced RISC (reduced instruction set computer) Machine (ARM) processor that allowed the execution of parallel tasks, fulfilling the real-time requirements that vehicle controls demand. Another feature of the proposed electronic system was the recording of measured data, allowing the performance of the implemented algorithm to be evaluated. All this was achieved by using modular programming that, without the need for a real-time operating system, executed the different tasks to be performed, exploiting the parallelism offered by the FPGA as well as the dual core of the ARM processor. This methodology facilitates the transition between the designing, testing, and implementation stages in the vehicle. In addition, our system is programmed with a single binary file that integrates the code of all processors as well as the hardware description of the FPGA, which speeds up the updating process. In order to validate and demonstrate the performance of the proposed electronic system as a tool for the development and implementation of control algorithms in vehicles, a series of tests was carried out on a test bench. Different traction control system (TCS) algorithms were implemented and the results were compared.

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