최근 교통감시시스템은 실시간의 영상검지시스템(VIPS)을 가장 선호하고 있으며, 그 수요는 매년 증가하고 있는 추세이다. 일반적으로 영상검지시스템은 공간기반의 검지알고리즘을 사용하고 있으며, 교통량, 속도, 점유율 등의 교통정보를 제공하고 있다. 현재 전 세계적으로 이미 상용화되어 있는 대부분의 영상검지시스템들은 Tripwire기반의 검지영역 내 차량의 존재유무를 판단하여 교통정보를 수집하는 알고리즘으로 구성되어 있으나, 개별차량에 대한 걸지는 불가능한 한계를 갖고 있다. 반면 개벽차량의 추적시스템은 보다 구체적인 공간적 교통정보를 제공할 수 있어 사고검지, 급차선 변경 등 교통정보를 보다 다양화 할 수 있다는 장점이 있으나 추적길이가 불과 100미터이내이면, 그 이상 관측하기 위해서는 운영자가 카메라를 줌인을 하여 영상을 확대하여야 한다. 따라서 본 논문에서는 차량 추적의 효과를 높이기 위해서 기존의 100미터 이내 추적거리를 여러 대의 CCTV시스템을 이용하더라도 200미터이상으로 확대함으로써 사고 또는 비정상적 차량흐름을 검지할 수 있는 알고리즘을 제안한다.
This paper presents a dynamic compensation methodology for robust trajectory tracking control of uncertain robot manipulators. To improve tracking performance of the system, a full model-based feedforward compensation with continuous VS-type robust control is developed in this paper(i.e,. robust decentralized adaptive control scheme). Since possible bounds of uncertainties are unknown, the adaptive bounds of the robust control is used to directly estimate the uncertainty bounds(instead of estimating manipulator parameters as in centralized adaptive control0. The global stability and robustness issues of the proposed control algorithm have been investigated extensively and rigorously via a Lyapunov method. The presented control algorithm guarantees that all system responses are uniformly ultimately bounded. Thus, it is shown that the control system is evaluated to be highly robust with respect to significant uncertainties.
Unlike normal wheels, the Mecanum wheel enables omni-directional movement regardless of the orientation of a mobile robot. In this paper, a robust trajectory tracking control method is developed based on the dynamic model of the Mecanum wheel mobile robot in order that the mobile robot can move along the given path in the environment with disturbance. The method is designed using the impedance control to make the mobile robot to track the path, and the integral sliding mode control for robustness to disturbance. The good performance of the proposed method is verified using the MATLAB /Simulink simulation and also through the experiment on an actual Mecanum wheel mobile robot. In both the simulation and the experimentation, we make the mobile robot move along a reference trajectory while maintaining the robot's orientation at a constant angle to see the characteristics of the Mecanum wheel.
A trajectory control system plays an important role in controlling motions of marine vehicle when a series of way points or a path is given. In this paper, a sliding mode control (SMC)-based trajectory tracking controller for marine vehicles is presented. A small-sized unmanned ship is considered as a control object. Both speed and heading angle of a ship should be controlled for tracking control. The common point of related researches was to separate ship's speed and heading angle in control methods. In this research, a new control law from a general sliding mode theory that can be applied to MIMO (multi input multi output) system is derived and both speed and heading angle of a ship can be controlled simultaneously. The propulsion force and rudder force are also applied in modeling stage to achieve accurate simulation. Disturbance induced by wind is also tackled in the dynamics considering robustness of the proposed control scheme. In the simulation, we employed a way-point method to generate ship's trajectory and applied the proposed control scheme to ship's trajectory tracking control. Our results confirmed that the tracking error was converged to zero, thus demonstrating the effectiveness of the proposed method.
Machining error makes the uncertainty of dimensional accuracy of the kinematic structure of a parallel robot system, which makes the uncertainty of kinematic accuracy of the end-effector of the parallel robot system. In this paper, the tendency of trajectory tracking error caused by the tolerance of design parameters of the parallel robot is analyzed. For this purpose, all the position errors are analyzed as the manipulator is moved on the target trajectory. X, Y, Z components of the trajectory errors are analyzed respectively, as well as resultant errors, which give the designer of the manipulator the intuitive and deep understanding on the effects of each design parameter to the trajectory tracking errors caused by the uncertainty of dimensional accuracy. The research results shows which design parameters are critically sensitive to the trajectory tracking error and the tendency of the trajectory tracking error caused by them.