Visual-Inertial SLAM Using a Monocular Camera and Detailed Map Data

Ekström, Viktor, Berglund, Ludvig

January 2023

The most commonly used localisation methods, such as GPS, rely on external signals to generate an estimate of the location. There is a need of systems which are independent of external signals in order to increase the robustness of the localisation capabilities. In this thesis a visual-inertial SLAM-based localisation system which utilises detailed map, image, IMU, and odometry data, is presented and evaluated. The system utilises factor graphs through Georgia Tech Smoothing and Mapping (GTSAM) library, developed at the Georgia Institute of Technology. The thesis contributes with performance evaluations for different camera and landmark settings in a localisation system based on GTSAM. Within the visual SLAM field, the thesis also contributes with a sparse landmark selection and a low image frequency approach to the localisation problem. A variety of camera-related settings, such as image frequency and amount of visible landmarks per image, are used to evaluate the system. The findings show that the estimate improve with a higher image frequency, and does also improve if the image frequency was held constant along the tracks. Having more than one landmark per image result in a significantly better estimate. The estimate is not accurate when only using one distant landmark throughout the track, but it is significantly better if two complementary landmarks are identified briefly along the tracks. The estimate can also handle time periods where no landmarks can be identified while maintaining a good estimate.

SLAM

localisation

monocular camera

GTSAM

factor graphs

iSAM2

Control Engineering

Reglerteknik

Lidar-based SLAM : Investigation of environmental changes and use of road-edges for improved positioning

Karlsson, Oskar

January 2020

The ability to position yourself and map the surroundings is an important aspect for both civilian and military applications. Global navigation satellite systems are very popular and are widely used for positioning. This kind of system is however quite easy to disturb and therefore lacks robustness. The introduction of autonomous vehicles has accelerated the development of local positioning systems. This thesis work is done in collaboration with FOI in Linköping, using a positioning system with LIDAR and IMU sensors in a EKF-SLAM system using the GTSAM framework. The goal was to evaluate the system in different conditions and also investigate the possibility of using the road surface for positioning. Data available at FOI was used for evaluation. These data sets have a known sensor setup and matches the intended hardware. The data sets used have been gathered on three different occasions in a residential area, a country road and a forest road in sunny spring weather on two occasions and one occasion in winter conditions. To evaluate the performance several different measures were used, common ones such as looking at positioning error and RMSE, but also the number of found landmarks, the estimated distance between landmarks and the drift of the vehicle. All results pointed towards the forest road providing the best positioning, the country road the worst and the residential area in between. When comparing different weather conditions the data set from winter conditions performed the best. The difference between the two spring data sets was quite different which indicates that there may be other factors at play than just weather. A road edge detector was implemented to improve mapping and positioning. Vectors, denoted road vectors, with position and orientation were adapted to the edge points and the change between these road vectors were used in the system using GTSAM in areas with few landmarks. The clearest improvements to the drift in the vehicle direction was in the longer country area where the error was lowered with 6.4 % with increase in the error sideways and in orientation as side effects. The implemented method has a significant impact on the computational cost of the system as well as requiring precise adjustment of uncertainty to have a noticeable improvement and not worsen the overall results.

lidar-slam

environmental

road-edges

gtsam

isam

evaluation

road-edge detector

ros

robot operating system

weather

rain

snow

rosnodes

slam

imu

ekf

extended kalmar filter

evaluation measures

Control Engineering

Reglerteknik