Model Predictive Control for Autonomous Driving Based on Time Scaled Collision Cone

Mithun Babu; Yash Oza; Arun Kumar Singh; K. Madhava Krishna; Shanti Medasani

doi:10.23919/ECC.2018.8550510

Model Predictive Control for Autonomous Driving Based on Time Scaled Collision Cone

Mithun Babu, Yash Oza, Arun Kumar Singh, K. Madhava Krishna, Shanti Medasani

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Scientific › peer-review

19 Citations (Scopus)

Abstract

In this paper, we present a Model Predictive Control (MPC) framework based on path velocity decomposition paradigm for autonomous driving. The optimization underlying the MPC has a two layer structure where in first, an appropriate path is computed for the vehicle followed by the computation of optimal forward velocity along it. The very nature of the proposed path velocity decomposition allows for seamless compatibility between the two layers of the optimization. A key feature of the proposed work is that it offloads most of the responsibility of collision avoidance to velocity optimization layer for which computationally efficient formulations can be derived. In particular, we extend our previously developed concept of time scaled collision cone (TSCC) constraints and formulate the forward velocity optimization layer as a convex quadratic programming problem.We perform validation on autonomous driving scenarios wherein proposed MPC repeatedly solves both the optimization layers in receding horizon manner to compute lane change, overtaking and merging maneuvers among multiple dynamic obstacles.

Original language	English
Title of host publication	2018 European Control Conference (ECC)
Publisher	IEEE
Pages	641-648
Number of pages	8
ISBN (Electronic)	978-3-9524-2698-2
ISBN (Print)	978-1-5386-5303-6
DOIs	https://doi.org/10.23919/ECC.2018.8550510
Publication status	Published - Jun 2018
Publication type	A4 Article in conference proceedings
Event	European Control Conference - Duration: 1 Jan 1900 → …

Conference

Conference	European Control Conference
Period	1/01/00 → …

Keywords

collision avoidance
convex programming
path planning
predictive control
quadratic programming
road traffic control
road vehicles
trajectory control
velocity control
path velocity decomposition paradigm
layer structure
optimal forward velocity
seamless compatibility
time scaled collision cone constraints
forward velocity optimization layer
convex quadratic programming problem
autonomous driving scenarios
optimization layers
MPC framework
model predictive control framework
TSCC constraints
lane change maneuver
overtaking maneuver
merging maneuver
Optimization
Collision avoidance
Trajectory
Autonomous vehicles
Robots
Dynamics
Planning

Publication forum classification

Publication forum level 1

Access to Document

10.23919/ECC.2018.8550510

Cite this

@inproceedings{6ee56a0eff594fb79ca50088ecdfcd44,

title = "Model Predictive Control for Autonomous Driving Based on Time Scaled Collision Cone",

abstract = "In this paper, we present a Model Predictive Control (MPC) framework based on path velocity decomposition paradigm for autonomous driving. The optimization underlying the MPC has a two layer structure where in first, an appropriate path is computed for the vehicle followed by the computation of optimal forward velocity along it. The very nature of the proposed path velocity decomposition allows for seamless compatibility between the two layers of the optimization. A key feature of the proposed work is that it offloads most of the responsibility of collision avoidance to velocity optimization layer for which computationally efficient formulations can be derived. In particular, we extend our previously developed concept of time scaled collision cone (TSCC) constraints and formulate the forward velocity optimization layer as a convex quadratic programming problem.We perform validation on autonomous driving scenarios wherein proposed MPC repeatedly solves both the optimization layers in receding horizon manner to compute lane change, overtaking and merging maneuvers among multiple dynamic obstacles.",

keywords = "collision avoidance, convex programming, path planning, predictive control, quadratic programming, road traffic control, road vehicles, trajectory control, velocity control, path velocity decomposition paradigm, layer structure, optimal forward velocity, seamless compatibility, time scaled collision cone constraints, forward velocity optimization layer, convex quadratic programming problem, autonomous driving scenarios, optimization layers, MPC framework, model predictive control framework, TSCC constraints, lane change maneuver, overtaking maneuver, merging maneuver, Optimization, Collision avoidance, Trajectory, Autonomous vehicles, Robots, Dynamics, Planning",

author = "Mithun Babu and Yash Oza and Singh, {Arun Kumar} and Krishna, {K. Madhava} and Shanti Medasani",

year = "2018",

month = jun,

doi = "10.23919/ECC.2018.8550510",

language = "English",

isbn = "978-1-5386-5303-6",

pages = "641--648",

booktitle = "2018 European Control Conference (ECC)",

publisher = "IEEE",

address = "United States",

note = "European Control Conference ; Conference date: 01-01-1900",

}

TY - GEN

T1 - Model Predictive Control for Autonomous Driving Based on Time Scaled Collision Cone

AU - Babu, Mithun

AU - Oza, Yash

AU - Singh, Arun Kumar

AU - Krishna, K. Madhava

AU - Medasani, Shanti

PY - 2018/6

Y1 - 2018/6

N2 - In this paper, we present a Model Predictive Control (MPC) framework based on path velocity decomposition paradigm for autonomous driving. The optimization underlying the MPC has a two layer structure where in first, an appropriate path is computed for the vehicle followed by the computation of optimal forward velocity along it. The very nature of the proposed path velocity decomposition allows for seamless compatibility between the two layers of the optimization. A key feature of the proposed work is that it offloads most of the responsibility of collision avoidance to velocity optimization layer for which computationally efficient formulations can be derived. In particular, we extend our previously developed concept of time scaled collision cone (TSCC) constraints and formulate the forward velocity optimization layer as a convex quadratic programming problem.We perform validation on autonomous driving scenarios wherein proposed MPC repeatedly solves both the optimization layers in receding horizon manner to compute lane change, overtaking and merging maneuvers among multiple dynamic obstacles.

AB - In this paper, we present a Model Predictive Control (MPC) framework based on path velocity decomposition paradigm for autonomous driving. The optimization underlying the MPC has a two layer structure where in first, an appropriate path is computed for the vehicle followed by the computation of optimal forward velocity along it. The very nature of the proposed path velocity decomposition allows for seamless compatibility between the two layers of the optimization. A key feature of the proposed work is that it offloads most of the responsibility of collision avoidance to velocity optimization layer for which computationally efficient formulations can be derived. In particular, we extend our previously developed concept of time scaled collision cone (TSCC) constraints and formulate the forward velocity optimization layer as a convex quadratic programming problem.We perform validation on autonomous driving scenarios wherein proposed MPC repeatedly solves both the optimization layers in receding horizon manner to compute lane change, overtaking and merging maneuvers among multiple dynamic obstacles.

KW - collision avoidance

KW - convex programming

KW - path planning

KW - predictive control

KW - quadratic programming

KW - road traffic control

KW - road vehicles

KW - trajectory control

KW - velocity control

KW - path velocity decomposition paradigm

KW - layer structure

KW - optimal forward velocity

KW - seamless compatibility

KW - time scaled collision cone constraints

KW - forward velocity optimization layer

KW - convex quadratic programming problem

KW - autonomous driving scenarios

KW - optimization layers

KW - MPC framework

KW - model predictive control framework

KW - TSCC constraints

KW - lane change maneuver

KW - overtaking maneuver

KW - merging maneuver

KW - Optimization

KW - Collision avoidance

KW - Trajectory

KW - Autonomous vehicles

KW - Robots

KW - Dynamics

KW - Planning

U2 - 10.23919/ECC.2018.8550510

DO - 10.23919/ECC.2018.8550510

M3 - Conference contribution

SN - 978-1-5386-5303-6

SP - 641

EP - 648

BT - 2018 European Control Conference (ECC)

PB - IEEE

T2 - European Control Conference

Y2 - 1 January 1900

ER -

Model Predictive Control for Autonomous Driving Based on Time Scaled Collision Cone

Abstract

Conference

Keywords

Publication forum classification

Access to Document

Fingerprint

Cite this