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

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

doi:10.3390/s19081834

Cited by 12 publications

(7 citation statements)

References 30 publications

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“…Several applications use interrupts to communicate between the PL and PS and combine hard real-time environments with soft real-time ones. In the automotive world, ECUs or autonomous driving are some examples [41,42]. Another example is audio or video stream data systems that usually work in real-time with an FIR filter in the PL [43].…”

Section: Hardware Designmentioning

confidence: 99%

Interrupt Latency Accurate Measurement in Multiprocessing Embedded Systems by Means of a Dedicated Circuit

Alonso,

Muguira,

Garate

et al. 2024

Electronics

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Modern multiprocessing embedded applications require, in many cases, two different environments on the same platform: one that meets real-time requirements and another one with a general purpose operating system. Although several technologies can be used, two of the most popular are virtualization based on hypervisors and asymmetric multiprocessing software. However, using these tools introduces latency, which must be measured to verify compliance with real-time requirements. With the aim of facilitating these measurements, this work provides a hardware tool that is more precise and easier to use than other existing software solutions. The paper also studies the interrupt latency generated by different hypervisors and asymmetric multiprocessing frameworks in a Zynq UltraScale+ platform. This research work facilitates the accurate study of the temporal response of multiprocessor embedded systems, which allows for evaluating their suitability for applications with real-time requirements.

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Section: Hardware Designmentioning

confidence: 99%

Interrupt Latency Accurate Measurement in Multiprocessing Embedded Systems by Means of a Dedicated Circuit

Alonso,

Muguira,

Garate

et al. 2024

Electronics

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“…It is notable that the proposed approximated methods do require more hardware resources (adders and multipliers) to get the optimized computation efficiency than the Runge-Kutta method, especially if more higher order terms are desired to improve the accuracy. However, as the embedded computation platforms like Field Programmable Gate Arrays (FPGAs) and portable General Purpose Graphic Processor Units (GPGPUs) are mushrooming, these additional costs become insignificant [36,37].…”

Section: Case Studymentioning

confidence: 99%

A Nonlinear Circuit Analysis Technique for Time-Variant Inductor Systems

Wang

Song

et al. 2019

Sensors

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Time-variant inductors exist in many industrial applications, including sensors and actuators. In some applications, this characteristic can be deleterious, for example, resulting in inductive loss through eddy currents in motors designed for high efficiency operation. Therefore, it is important to investigate the electrical dynamics of systems with time-variant inductors. However, circuit analysis with time-variant inductors is nonlinear, resulting in difficulties in obtaining a closed form solution. Typical numerical algorithms used to solve the nonlinear differential equations are time consuming and require powerful processors. This investigation proposes a nonlinear method to analyze a system model consisting of the time-variant inductor with a constraint that the circuit is powered by DC sources and the derivative of the inductor is known. In this method, the Norton equivalent circuit with the time-variant inductor is realized first. Then, an iterative solution using a small signal theorem is employed to obtain an approximate closed form solution. As a case study, a variable inductor, with a time-variant part stimulated by a sinusoidal mechanical excitation, is analyzed using this approach. Compared to conventional nonlinear differential equation solvers, this proposed solution shows both improved computation efficiency and numerical robustness. The results demonstrate that the proposed analysis method can achieve high accuracy.

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“…An electronic CU is designed by authors on FPGA for controlling the vehicles' system. The Reduced Instruction Set Computer (RISC) Machine (ARM) processor is used along with FPGA for computing parallel tasks (Pérez et al, 2019). To promote the ideas of green communication researchers have implemented a power-efficient CU on Virtex and Spartan family's FPGA (Pandey, 2020).…”

Section: Introductionmentioning

confidence: 99%

Implementation of Power-Efficient Control Unit on Ultra-scale FPGA for Green Communication

Pandey¹,

Kumar²,

Batool³

et al. 2021

3C Tecnología

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Whole world is suffering from the problem of the energy crisis. This is happening because of the enormous growth of population and industries across the globe. Therefore the whole world is looking to adopt the concepts of green communication technologies and power/energy efficient devices. This work is just towards these technologies. In this work, a power-efficient Control Unit (CU) is designed and implemented on Kintex-7 Ultrascale FPGA. The simulation and power analysis of the control unit is done on VIVADO HLx Design Suite. The power analysis of control unit is observed for different frequency values and it is observed that as the frequency increases the total power consumption also increases. Hence the control unit is more suitable to operate at low frequency values in order to minimize the power consumption. Also, there is a 36% saving in total power consumption when we scale down the device operating frequency of the control unit from 5 GHz to 100 MHz.

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

Cited by 12 publications

References 30 publications

Interrupt Latency Accurate Measurement in Multiprocessing Embedded Systems by Means of a Dedicated Circuit

Interrupt Latency Accurate Measurement in Multiprocessing Embedded Systems by Means of a Dedicated Circuit

A Nonlinear Circuit Analysis Technique for Time-Variant Inductor Systems

Implementation of Power-Efficient Control Unit on Ultra-scale FPGA for Green Communication

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