The recent advances in sensing and display technologies have been transforming our living environments drastically. In this paper, a new technique is introduced to accurately reconstruct indoor environments in three-dimensions using a mobile platform. The system incorporates 4 ultrasonic sensors scanner system, an HD web camera as well as an inertial measurement unit (IMU). The whole platform is mountable on mobile facilities, such as a wheelchair. The proposed mapping approach took advantage of the precision of the 3D point clouds produced by the ultrasonic sensors system despite their scarcity to help build a more definite 3D scene. Using a robust iterative algorithm, it combined the structure from motion generated 3D point clouds with the ultrasonic sensors and IMU generated 3D point clouds to derive a much more precise point cloud using the depth measurements from the ultrasonic sensors. Because of their ability to recognize features of objects in the targeted scene, the ultrasonic generated point clouds performed feature extraction on the consecutive point cloud to ensure a perfect alignment. The range measured by ultrasonic sensors contributed to the depth correction of the generated 3D images (the 3D scenes). Experiments revealed that the system generated not only dense but precise 3D maps of the environments. The results showed that the designed 3D modeling platform is able to help in assistive living environment for self-navigation, obstacle alert, and other driving assisting tasks.
References
[1]
Caruso, D., Engel, J. and Cremers, D. (2015) Large-Scale Direct SLAM for Omni-Directional Cameras. Proceedings of the 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Hamburg, Germany, 28 September 2015-2 October 2015, 141-148. https://doi.org/10.1109/IROS.2015.7353366
[2]
Longuet-Higgins, H.C. (1981) A Computer Algorithm for Reconstructing a Scene from Two Projections. Nature, 293, 133-135.
[3]
Tomasi, C. and Kanade, T. (1992) Shape and Motion from Image Streams under Orthography: A Factorization Method. International Journal of Computer Vision, 9, 137-154. https://doi.org/10.1007/BF00129684
[4]
Zhang, Q.L. and Pless, R. (2004) Extrinsic Calibration of a Camera and Laser Range Finder (Improves Camera Calibration). Department of Computer Science and Engineering, Washington University, St. Louis.
[5]
Shi, X.Y., Peng, J.J., Li, J.P., Yan, P.T. and Gong, H.Y. (2019) The Iterative Closest Point Registration Algorithm Based on the Normal Distribution Transformation. Procedia Computer Science, 147, 181-190.
[6]
Han, J., Yin, P., He, Y. and Gu, F. (2016) Enhanced ICP for the Registration of Large-Scale 3D Environment Models: An Experimental Study. Sensors, 16, 228. https://doi.org/10.3390/s16020228
[7]
Gressin, A., Mallet, C., Demantké, J. and David, N. (2013) Towards 3D Lidar Point Cloud Registration Improvement Using Optimal Neighborhood Knowledge. ISPRS Journal of Photogrammetry and Remote Sensing, 79, 240-251. https://doi.org/10.1016/j.isprsjprs.2013.02.019
[8]
Abdullah, R.H. (2015) Design and Implementation of Ultrasonic Based Distance Measurement Embedded System with Temperature Compensation. International Journal of Emerging Science and Engineering (IJESE), 3, No. 8.
[9]
Rhee, J.H. and Seo, J. (2019) Low-Cost Curb Detection and Localization System Using Multiple Ultrasonic Sensors. Sensors, 19, 1389. https://doi.org/10.3390/s19061389
