Parking Robot Path-Tracking System Based on Discrete PID Algorithm

IF 0.7 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Dianjun Wang, Jiahao Chen, Ya Chen, Xingkang Zheng, Liang Wang, Lele Wang
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引用次数: 0

Abstract

To improve the space utilization rates of intelligent stereo garages, their key execution equipment—parking robots—must be highly flexible; therefore, the chassis of parking robots use steering wheel systems. However, this design increases the complexity of robot motion control and path-tracking systems. Because of the large sizes of parking robots, large position and angle deviations can lead to derailment events, posing significant risk to users. Thus, in this study, based on the characteristics required for parking robots, a diagonally arranged parking robot with double steering wheels was developed and its kinematic model was established using the velocity–geometry method. For the positioning of the robot in a garage, a fusion positioning algorithm based on quick response (QR) codes and track calculation was used, considering the requirements of real-time response and accuracy. A discrete proportional-integral-derivative (PID) path-tracking algorithm for the synchronous compensation of the position and angle deviations was also devised. Using the Visual C++ platform, a path-tracking system that uses an industrial computer and motion control card was developed. Experiments on the path-tracking capability of the parking robot showed that, using the discrete PID path-tracking algorithm, it can track a planned path well. On Z- and U-type paths, its maximum tracking deviations were reduced by 84.8% and 64.0%, compared with the unused path-tracking system, reaching 10.4 mm and 10.9 mm, respectively. Thus, the tracking accuracy was significantly improved, proving that the developed robot well satisfies the path-tracking requirements of parking robots.
基于离散PID算法的停车机器人路径跟踪系统
为了提高智能立体车库的空间利用率,其关键执行设备停车机器人必须具有高度的灵活性;因此,泊车机器人的底盘采用方向盘系统。然而,这种设计增加了机器人运动控制和路径跟踪系统的复杂性。由于停车机器人的尺寸较大,较大的位置和角度偏差可能导致脱轨事件,对用户构成重大风险。因此,本研究根据泊车机器人所需的特性,研制了一种对角线布置的双方向盘泊车机器人,并采用速度几何方法建立了其运动学模型。针对车库机器人的定位,考虑到实时性和准确性的要求,采用了基于QR码和轨迹计算的融合定位算法。设计了一种离散比例-积分-导数(PID)路径跟踪算法,用于位置和角度偏差的同步补偿。在Visual c++平台上,开发了一个由工控机和运动控制卡组成的路径跟踪系统。对停车机器人路径跟踪能力的实验表明,采用离散PID路径跟踪算法可以很好地跟踪规划的路径。在Z型和u型路径上,与未使用路径跟踪系统相比,其最大跟踪偏差减小了84.8%和64.0%,分别达到10.4 mm和10.9 mm。因此,跟踪精度显著提高,证明所开发的机器人很好地满足了停车机器人的路径跟踪要求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
1.50
自引率
14.30%
发文量
89
期刊介绍: JACIII focuses on advanced computational intelligence and intelligent informatics. The topics include, but are not limited to; Fuzzy logic, Fuzzy control, Neural Networks, GA and Evolutionary Computation, Hybrid Systems, Adaptation and Learning Systems, Distributed Intelligent Systems, Network systems, Multi-media, Human interface, Biologically inspired evolutionary systems, Artificial life, Chaos, Complex systems, Fractals, Robotics, Medical applications, Pattern recognition, Virtual reality, Wavelet analysis, Scientific applications, Industrial applications, and Artistic applications.
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