Autonomous vehicle following : a virtual trailer link approach
This thesis addresses the automation of the vehicle following function in an urban city environment, i.e., travelling under heavy traffic conditions or in a ‘stop-and-go’ motion. A virtual trailer link model for vehicle following has been proposed. With this perspective, the leader is represented...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2009
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/18901 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This thesis addresses the automation of the vehicle following function in an
urban city environment, i.e., travelling under heavy traffic conditions or in a
‘stop-and-go’ motion. A virtual trailer link model for vehicle following has been
proposed. With this perspective, the leader is represented as a tractor pulling
the follower, which is modelled as a trailer, in the form of a virtual link. The
optimum configuration and the length of the virtual trailer link model have been
determined by taking into consideration the safe following distance as well as
general car-like vehicle dynamics and constraints. In implementing the virtual
trailer link model for vehicle following, sensors are required for the estimation
of the relative pose and velocity of the lead vehicle in relation to the follower.
However, inherent sensor noise, as well as limitations on their fields of view
and resolution can affect the performance of the vehicle following function. A
Bayesian formulation is thus proposed to model the process and sensor noise
in the system. The key to a tractable solution for this formulation is based
on the justified assumption that the pose of the follower vehicle is statistically
independent of that of the leader. By estimating the poses of both vehicles,
together with the uncertainties of the system, it is possible to minimize the
path deviations between them. Moreover, as a result of uncertainties in the system, the computed driving commands based on the virtual trailer link model need to be optimized. Hence, a metric is required to evaluate and optimize the
driving commands for the follower vehicle. An information theoretic framework
is proposed. The aim of this framework is to select an optimal control input to
the follower so as to minimize the pose error between the vehicles. Under this
framework, the relative information has been used as a metric to evaluate a sequence of controlling actions, which act as inputs to the follower vehicle. |
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