模糊逻辑推理在消除交通流诱导负效应中的应用

针对交通流诱导可能产生的负效应问题,提出了诱导负效应消除的原理和模糊逻辑推理方法。在原理设计中,考虑了出行者的出行行为对网络交通流分配的影响;在实现方法上,应用模糊推理技术对分流交通量进行了预测,并设计了路线交叉口信号灯配时方案调整的模糊控制算法,模拟结果验证了模糊逻辑推理技术的有效性。研究表明:交通流诱导负效应的产生主要是由于信息条件下的道路出行者路线选择行为的不确定性引起的,而且交通流诱导与控制同时进行是消除交通流诱导负效应产生的关键。     

燃料电池船舶复合供能系统控制策略设计与仿真

针对燃料电池船舶复合供能系统中的燃料电池功率波动问题和储能单元电池荷电状态（State of Charge,SOC）极端分化问题,依据系统拓扑结构,提出基于负载功率频率分解与模糊逻辑控制法相结合的复合供能系统控制策略设计。采用实例仿真验证该设计的优势。结果表明,该设计可有效保持燃料电池输出功率平滑,对储能单元SOC具有良好的均衡控制效果。     

基于PCA-聚类分析的高铁旅客购票行为特性研究

铁路运输中旅客购票行为是铁路客运运营策略制定的重要基础.旅客购票行为直接影响着列车能力的占用过程,是铁路客运票额组织的重要依据.根据贵阳—广州高速铁路的旅客购票统计数据,以高铁购票旅客为样本,运用主成分分析法购票行为的特征属性进行综合分析,获得购票行为中重要特征变量.结合单次购票强度提出基于模糊C均值的双重聚类算法,对购票旅客进行聚类,并利用模糊聚类有效性指标Xie-beni和分离系数法确定最佳聚类数.结果表明,高铁旅客购票行为的关键特性为单次出行旅客人数、购票提前天数、出行OD城市人均GDP和购票渠道;不同旅客类型的购票行为有明显特性.     

机车模糊粘着控制及其仿真研究

简要讨论了目前机车空转识别方法和主要的防空转，粘着控制方法，提出了一种转趋势识别方法；基于此方法，利用模糊控制理论进行了优化着模糊控制的研究，仿真结果表明，上述方法能在发生空转前及时抑制空转发生，并最大限度利用粘着力，实现了优化粘着控制。     

Fuzzy and adaptive fuzzy control for the automobiles’ active suspension system

Two typical criteria for good vehicle suspension performance are their ability to provide good road handling and increased passenger comfort. The main disturbance affecting these two criteria is terrain irregularities. Active suspension control systems reduce these undesirable effects by isolating car body motion from vibrations at the wheels. This paper describes fuzzy and adaptive fuzzy control (AFC) schemes for the automobile active suspension system (ASS). The design objective is to provide smooth vertical motion so as to achieve the road holding and riding comfort over a wide range of road profiles. The efficacy of the proposed control schemes is demonstrated via simulations. With respect to the optimal linear quadratic regulator (LQR), it is shown that superior results have been achieved by the AFC.     

Enhancing grey prediction fuzzy controller for active suspension systems

A grey prediction fuzzy controller (GPFC) was proposed to control an active suspension system and evaluate its control performance. The GPFC employed the grey prediction algorithm to predict the position output error of the sprung mass and the error change as input variables of the traditional fuzzy controller (TFC) in controlling the suspension system to suppress the vibration and the acceleration amplitudes of the sprung mass for improving the ride comfort of the TFC used; however, the TFC or GPFC was employed to control the suspension system, resulting in a large tire deflection so that the road-holding ability in the vehicle becomes worse than with the original passive control strategy. To overcome the problem, this work developed an enhancing grey prediction fuzzy controller (EGPFC) that not only had the original GPFC property but also introduced the tire dynamic effect into the controller design, also using the grey prediction algorithm to predict the next tire deflection error and the error change as input variables of another TFC, to control the suspension system for enhancing the road-holding capability of the vehicle. The EGPFC has better control performances in suppressing the vibration and the acceleration amplitudes of the sprung mass to improve the ride quality and in reducing the tire deflection to enhance the road-holding ability of the vehicle, than both TFC and GPFC, as confirmed by experimental results.     

A novel fuzzy logic correctional algorithm for traction control systems on uneven low-friction road conditions

The traction control system (TCS) might prevent excessive skid of the driving wheels so as to enhance the driving performance and direction stability of the vehicle. But if driven on an uneven low-friction road, the vehicle body often vibrates severely due to the drastic fluctuations of driving wheels, and then the vehicle comfort might be reduced greatly. The vibrations could be hardly removed with traditional drive-slip control logic of the TCS. In this paper, a novel fuzzy logic controller has been brought forward, in which the vibration signals of the driving wheels are adopted as new controlled variables, and then the engine torque and the active brake pressure might be coordinately re-adjusted besides the basic logic of a traditional TCS. In the proposed controller, an adjustable engine torque and pressure compensation loop are adopted to constrain the drastic vehicle vibration. Thus, the wheel driving slips and the vibration degrees might be adjusted synchronously and effectively. The simulation results and the real vehicle tests validated that the proposed algorithm is effective and adaptable for a complicated uneven low-friction road.     

机车调车作业安全的多层次模糊综合评价

以大连铁路分局某货运站机车调画作业安全为例，动用模糊数学理论，在原有的一级评价模型的基础上，建立了多层次安全评价模型，该模型克服了一级评价模型在处理复杂系统过程， 因评价因素我，权系数很小，经过Ｆｕｚｚｙ矩阵的复合运算丢失许多有作用信息的弱点，     

基于模糊时间Petri网的列车运行时间不确定性问题的处理

定义一种应用于铁路列车运行系统的模糊时间Petri网；针对列车运行时间存在的不确定性，该Petri网引入了4个模糊集理论函数：模糊时间片、模糊使能时间、模糊发生时间和模糊延迟，来处理时间的不确定性问题；能够对列车运行过程中的时间不确定性问题进行定量分析，可以有效应用于列车交会、列车终到时间、列车运行计划调整的分析等；其相对于已有的方法具有精确分析、计算简单、简化系统、便于系统集成的特点。     

SS4改型机车安装逻辑控制装置的改进设计

介绍了几种国产电力机车安装逻辑控制装置的现状及特点,从机车布置、重联方案的确定与逻辑关系的实现等方面,说明了SS4改型机车安装逻辑控制装置的改进设计。