Stability-Preserving Slip Control of Articulated Heavy Vehicles Using Adaptive Longitudinal Slip Limits Derived from Phase Portraits
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Publicerad
Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
Tidskriftstitel
ISSN
Volymtitel
Utgivare
Sammanfattning
Ensuring the lateral stability of articulated heavy vehicles (AHVs) is critical for road
safety, as they are susceptible to dangerous instability modes like jackknifing and
trailer swing. Conventional stability control systems often rely on fixed slip thresholds,
which may utilize higher slip limits than the proven safe limits under certain
conditions, such as dynamic maneuvers involving high lateral accelerations. This
thesis proposes an adaptive framework that determines safe longitudinal slip limits
using phase portrait analysis.
A computationally efficient, non-linear single-track model of a tractor-semitrailer
combination was developed and validated against the high-fidelity simulation environment,
Volvo Transport Model (VTM). The core of the methodology involves
reducing the complex dynamics into a series of 2D phase planes for both the tractor
and trailer units. Stability for each point on the phase plane is systematically
classified using Largest Lyapunov Exponent (LLE), allowing for the automated generation
of Safe Operating Envelopes (SOEs).
This work establishes a robust methodology for generating state-dependent stability
limits, laying the foundation for advanced control allocation strategies that can enhance
the safety of AHVs by dynamically constraining actuator requests to remain
within a safe region.
The practical utility of this framework was demonstrated by designing and implementing
two distinct control strategies in VTM. The first, an offline controller,
utilizes the pre-computed SOEs as a multi-dimensional lookup table to adaptively
constrain driver slip requests. The second, an online controller, was developed to
generate these stability limits dynamically within the simulation, showcasing a pathway
toward fully adaptive in-vehicle systems. The performance of both controllers
confirms that the SOE-based approach can effectively prevent instability while maximizing
the vehicle’s handling limit.
Beskrivning
Ämne/nyckelord
articulated heavy vehicles, jack-knifing, trailer swing, adaptive longitudinal slip, phase portrait, safe operating envelope, control allocation
