Adaptive automotive communications solutions of 10 years lifetime enabled by ETSI RRS software reconfiguration technology

Jin, Yong; Ahn, Heungseop; Kim, Kyunghoon; Choi, Sangdun; Mueck, Markus; Frascolla, Valerio; Haustein, Thomas

doi:10.23919/eusipco.2017.8081338

Cited by 2 publications

(2 citation statements)

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“…Through complete digitization, the vehicles and all the elements related to the transportation system are evolving into sophisticated, interconnected complex-networked mobile computers. In particular, this aspect includes various networked microprocessor-based electronic control units (ECU) that enhance their functions and serve as a foundation for continuous control [3,4]. Notably, the real-time estimation of data regarding the changes in vehicle's velocity components plays a vital role in three key areas: For what concerns the driving assistance systems, the increasing level of vehicle dependence on software has made complex control systems essential for modern vehicle development.…”

Section: Introductionmentioning

confidence: 99%

Four-Wheeled Vehicle Sideslip Angle Estimation: A Machine Learning-Based Technique for Real-Time Virtual Sensor Development

Napolitano Dell’Annunziata,

Ruffini,

Stefanelli

et al. 2024

Applied Sciences

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In the last few decades, the role of vehicle dynamics control systems has become crucial. In this complex scenario, the correct real-time estimation of the vehicle’s sideslip angle is decisive. Indeed, this quantity is deeply linked to several aspects, such as traction and stability optimization, and its correct understanding leads to the possibility of reaching greater road safety, increased efficiency, and a better driving experience for both autonomous and human-controlled vehicles. This paper aims to estimate accurately the sideslip angle of the vehicle using different neural network configurations. Then, the proposed approach involves using two separate neural networks in a dual-network architecture. The first network is dedicated to estimating the longitudinal velocity, while the second network predicts the sideslip angle and takes the longitudinal velocity estimate from the first network as input. This enables the creation of a virtual sensor to replace the real one. To obtain a reliable training dataset, several test sessions were conducted on different tracks with various layouts and characteristics, using the same reference instrumented vehicle. Starting from the acquired channels, such as lateral and longitudinal acceleration, steering angle, yaw rate, and angular wheel speeds, it has been possible to estimate the sideslip angle through different neural network architectures and training strategies. The goodness of the approach was assessed by comparing the estimations with the measurements obtained from an optical sensor able to provide accurate values of the target variable. The obtained results show a robust alignment with the reference values in a great number of tested conditions. This confirms that the adoption of artificial neural networks represents a reliable strategy to develop real-time virtual sensors for onboard solutions, expanding the information available for controls.

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Section: Introductionmentioning

confidence: 99%

Four-Wheeled Vehicle Sideslip Angle Estimation: A Machine Learning-Based Technique for Real-Time Virtual Sensor Development

Napolitano Dell’Annunziata,

Ruffini,

Stefanelli

et al. 2024

Applied Sciences

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“…In recent decades, the development of increasingly advanced automotive safety technologies and collision avoidance assistance systems, the expectation with the intelligent and autonomous transportation system and the growing affluence in individual mobility have been accelerated to enhance not only the performance of active safety technologies against car accidents but also to reduce traffic congestion and improve global traffic efficiency [ 1 , 2 , 3 , 4 ]. With end-to-end digitization, beginning with the individual automobile through all elements of the transportation system from road infrastructure to back-end server, vehicles are becoming complex networked mobile computers, including various networked microprocessor-based ECUs that enhance vehicle functionality and provide a general basis for uninterrupted control and management of traffic flow [ 5 , 6 , 7 ].…”

Section: Introductionmentioning

confidence: 99%

Estimation of Vehicle Longitudinal Velocity with Artificial Neural Network

Dell’Annunziata

Arricale

Farroni

et al. 2022

Sensors

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Vehicle dynamics control systems have a fundamental role in smart and autonomous mobility, where one of the most crucial aspects is the vehicle body velocity estimation. In this paper, the problem of a correct evaluation of the vehicle longitudinal velocity for dynamic control applications is approached using a neural networks technique employing a set of measured samples referring to signals usually available on-board, such as longitudinal and lateral acceleration, steering angle, yaw rate and linear wheel speed. Experiments were run on four professional driving circuits with very different characteristics, and the vehicle longitudinal velocity was estimated with different neural network training policies and validated through comparison with the measurements of the one acquired at the vehicle’s center of gravity, provided by an optical Correvit sensor, which serves as the reference (and, therefore, exact) velocity values. The results obtained with the proposed methodology are in good agreement with the reference values in almost all tested conditions, covering both the linear and the nonlinear behavior of the car, proving that artificial neural networks can be efficiently employed onboard, thereby enriching the standard set of control and safety-related electronics.

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Adaptive automotive communications solutions of 10 years lifetime enabled by ETSI RRS software reconfiguration technology

Cited by 2 publications

References 0 publications

Four-Wheeled Vehicle Sideslip Angle Estimation: A Machine Learning-Based Technique for Real-Time Virtual Sensor Development

Four-Wheeled Vehicle Sideslip Angle Estimation: A Machine Learning-Based Technique for Real-Time Virtual Sensor Development

Estimation of Vehicle Longitudinal Velocity with Artificial Neural Network

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