Comparison of Anti-Jerk Controllers for Electric Vehicles With On-Board Motors

Scamarcio, Alessandro; Metzler, Mathias; Gruber, Patrick; Pinto, Stefano De; Sorniotti, Aldo

doi:10.1109/tvt.2020.2997815

Cited by 16 publications

(20 citation statements)

References 44 publications

(71 reference statements)

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“…All proposed controllers are based on realistic assumptions in terms of required state estimators. In fact, a wide literature covers state estimators of individual tire slip [9], [26], as well as half-shaft torsion and half-shaft torque [2], [20], [27], including examples of experimental validation on real vehicles [9], [26], [28].…”

Section: A Evaluated Configurationsmentioning

confidence: 99%

“…The literature includes a variety of model predictive traction controllers [16]- [19] and anti-jerk controllers [2], [20] without road preview, all of them defining the wheel slip control problem only for a single wheel. In [21] Batra et al propose a model predictive adaptive cruise controller with traction control capability, achieved through a hard constraint on the longitudinal tire slip.…”

mentioning

confidence: 99%

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Predictive Anti-Jerk and Traction Control for V2X Connected Electric Vehicles With Central Motor and Open Differential

Scamarcio

Caponio

Mihalkov

et al. 2023

IEEE Trans. Veh. Technol.

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V2X connectivity and powertrain electrification are emerging trends in the automotive sector, which enable the implementation of new control solutions. Most of the production electric vehicles have centralized powertrain architectures consisting of a single central on-board motor, a single-speed transmission, an open differential, half-shafts, and constant velocity joints. The torsional drivetrain dynamics and wheel dynamics are influenced by the open differential, especially in split-𝝁 scenarios, i.e., with different tire-road friction coefficients on the two wheels of the same axle, and are attenuated by the socalled anti-jerk controllers. Although a rather extensive literature discusses traction control formulations for individual wheel slip control, there is a knowledge gap on: a) model based traction controllers for centralized powertrains; and b) traction controllers using the preview of the expected tire-road friction condition ahead, e.g., obtained through V2X, for enhancing the wheel slip tracking performance. This study presents nonlinear model predictive control formulations for traction control and anti-jerk control in electric powertrains with central motor and open differential, and benefitting from the preview of the tire-road friction level. The simulation results in straight line and cornering conditions, obtained with an experimentally validated vehicle model, as well as the proof-of-concept experiments on an electric quadricycle prototype, highlight the benefits of the novel controllers.

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Section: A Evaluated Configurationsmentioning

confidence: 99%

mentioning

confidence: 99%

Predictive Anti-Jerk and Traction Control for V2X Connected Electric Vehicles With Central Motor and Open Differential

Scamarcio

Caponio

Mihalkov

et al. 2023

IEEE Trans. Veh. Technol.

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“…Jerk in unmanned aerial vehicle (UAV) [11,[178][179][180][181][182][183][184][185][186]; and 21. Jerk in vehicles (ride comfort [12,15,17,19,25,45,95,98-106,108,109,111-113,115,118-121, 123-125,127-131], anti-jerk controller design [95,[98][99][100][101][102]109,111,119,120,130], autonomous vehicles [12,16,114,123,187,188], and other [111,187,[189][190][191][192][193][194][195].…”

Section: Categorisation Of Jerk Applicationsmentioning

confidence: 99%

“…Ride comfort is an important parameter in amusement rides [1,4,5], sea-keeping [9,10,122,126] and traditional land-based vehicles [12,25,45,95,[98][99][100][101][102][103][104][105][106]108,109,[111][112][113]115,[118][119][120][121][123][124][125][127][128][129][130][131]. There are still discussions ongoing regarding the significance of jerk regarding ride comfort for vehicles, and jerk is probably a better measure for driving comfort than acceleration, as pointed out by van Santen [128] and confirmed, e.g., in the study by Grant and Haycock [107].…”

Section: Jerk In Criteria For Discomfortmentioning

confidence: 99%

“…Jerk in vehicles is mainly used for measuring the ride comfort [12,25,45,95,98-106,108,109,111-113, 115,118-121,123-125,127-131]. It is also used as a controller design, referred to as an anti-jerk controller design [95,[98][99][100][101][102]109,111,119,120,130]. Jerk is also used in autonomous vehicles [12,114,123,187,188], which is explained in the below sections.…”

Section: Jerk In Vehicles-land Based Traditionalmentioning

confidence: 99%

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Jerk within the Context of Science and Engineering—A Systematic Review

et al. 2020

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Rapid changes in forces and the resulting changes in acceleration, jerk and higher order derivatives can have undesired consequences beyond the effect of the forces themselves. Jerk can cause injuries in humans and racing animals and induce fatigue cracks in metals and other materials, which may ultimately lead to structure failures. This is a reason that it is used within standards for limits states. Examples of standards which use jerk include amusement rides and lifts. Despite its use in standards and many science and engineering applications, jerk is rarely discussed in university science and engineering textbooks and it remains a relatively unfamiliar concept even in engineering. This paper presents a literature review of the jerk and higher derivatives of displacement, from terminology and historical background to standards, measurements and current applications.

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