['FastSLAM is one of the most popular algorithms for solving the simultaneous localization and mapping problem. Though the effectiveness of FastSLAM2.0 is better than that of EKF-SLAM, its performance tends to slow down as the number of landmarks increases. Therefore, this thesis proposes an improved version, called Rapid Operation SLAM (ROSLAM), which uses the convergence of the particles to decide whether the current measurements should be used to update the robot’s pose or not. ROSLAM checks the number of landmarks as compared to the previous one and uses this information to decide whether to update a landmark’s position or not. Empirical evaluation using both simulation and practical experiments shows that ROSLAM is 50% faster than FastSLAM while maintaining similar accuracy of the map. Since laser scan provides clear 3D points clouds, most SLAM research uses laser scanners in spite of the high cost, weight, and power consumption. As a result, a visual SLAM system is proposed in this thesis. First, image processing technique is adopted to find the feature points between obstacles and the floor, so as to calculate the distances between the robot and the feature points. Experimental results show that the proposed system provides sufficient information for a practical visual SLAM system. ']