Tightly Coupled Multimodal Sensor Data Fusion for Robust State Observation With Online Delay Estimation and Compensation

Abstract

Ego-vehicle state estimation can be achieved by utilizing classic vehicle and environmental sensors. However, each type of sensor has specific strengths and limitations regarding accuracy and robustness. Using existing sensor concept cannot fulfill the requirements for both accuracy and robustness against changing vehicle parameters and environments while driving. Therefore, we propose a framework to exploit the advantages of each individual sensor type seeking high accuracy and robustness. The uncertainty of state variables is estimated by the fusion of an inertial measurement unit, a global navigation satellite system, a radar sensor, and a lidar sensor. The multimodal sensor data are processed in a distributed manner in each sensor model at a low level, and the physical quantities from the sensor models are fused centrally by a probabilistic method, namely, the synchronized error-state extended Kalman filter, at a high level. We propose an event-based approach to estimate sensor system delay and compensate lagged signals using forward prediction fusion. The concept was implemented in a test vehicle and evaluated in field tests for dynamic driving and on public roads. The algorithm represents real-time estimation with high accuracy for different driving maneuvers and robustness against different disturbances caused by the environment and changing chassis parameters.