不对称边跨预应力混凝土连续梁桥施工监控

该文介绍了312国道常州段新武宜运河大桥不对称边跨预应力混凝土连续箱梁施工监控的关键技术,论述了施工监控的目的与意义,阐明了线形控制及应力监测的要求、技术措施等。     

山区GPS高程转换的探讨

 GPS高程转换的核心问题就是高程异常计算，本文指出了现有算法的不足，推导出更加完善的连续型积分计算公式。该公式在计算过程中无须人工干预，避免了人为误差的影响，并通过试验分析了山区、高山区不同参考面高程对高程异常计算值的影响。在高程拟合方面，对普通的高程拟合进行了改进，给出了一个附加参数的高程拟合模型，试验结果显示这个改进显著提高了高程拟合精度，更加适用于山区GPS高程转换，并把该理论模型用于现场GPS高程测量与实际高程比较。     

国际平整度指数二元曲面函数描述模型的研究

通过建立国际平整度指数(IR I)的数字地面模型来描述基于道路面状的IRI指标概念。在分析研究几类数字地面模型的曲面函数内插方法的基础上,给出了IRI的二元双一次曲面乘积型逼近模型。最后给出了定义和描述同一段道路路面不同时段IRI变化量的乘积型重积分求积公式、IRI均值和标准差、IRI值的变化差均值及IRI值变化差的标准差、IRI值单位时间变化速率等数值解法。     

用于车道识别的分段切换车道模型

为了使得车道模型既能准确地描述车道形状,又不影响车道识别算法的实时性,提出了一种分段切换车道模型。对近视场区域使用直线模型匹配车道线,对远视场区域则在直线模型和二次曲线模型之间进行切换,以适应有曲率和无曲率道路的识别要求。试验表明,使用分段切换车道模型的车道识别算法能够很好地匹配各种形状道路,并能满足实时性要求。     

动态分段技术在路面管理系统中的应用

动态分段技术是一项新的线性特征的存储、显示和分析技术,已经开始应用于路面管理系统。该文介绍了动态分段技术中的基本概念及其基本原理,分析了路面管理系统中动态分段的数据结构并结合实例介绍了其在该系统中的应用。     

数字电子调速器的设计与应用

数字电子调速器是实现直列柱塞泵柴油机电子控制的有效方案.介绍了利用线性比例电磁铁作为执行器,以Mortorola的MC9S12DP256 MCU为主控芯片,在CodeWarrier集成开发环境下开发了相应的控制程序,实现了柴油机的数字调速,并应用于LR6105Q柴油机.测试结果表明,发动机稳态调速率小于2.5%,符合各类常规设备动力的调速要求;发动机的两级调速转矩特性符合车辆的动力特性要求.     

基于Synchro的多交叉口交通信号控制研究

分析了城市道路交叉口的平均延误时间、道路通行能力和信号配时的数学模型和计算方法。在对宝鸡市的22个主要信控交叉口进行了大量的交通调研的基础上，选取了有代表性的太白路、公园路上多个交叉口作为协调控制交叉口，阐述了交叉口信号协调控制系统的设计方法。最后通过公式计算和Synchro系统仿真的两种方法，对线控前后的系统进行了对比，结果表明宝鸡市受控干道交叉口的延误和通行能力得到了明显的改善。     

公路土石方调配优化数学模型的建立和程序设计

线性规划运输平衡问题数学模型应用于公路土石方调配，综合考虑借，弃方单价及和纵向调配运价，以最小费用为目标函数，调配方量为决策变量，调配单位（元／m^3）为价值系数，编制程序完成实现最小费用的优化调配方案，并根据需要统计输各项表格。     

Optimization models for differentiating quality of service levels in probabilistic network capacity design problems

This paper develops various chance-constrained models for optimizing the probabilistic network design problem (PNDP), where we differentiate the quality of service (QoS) and measure the related network performance under uncertain demand. The upper level problem of PNDP designs continuous/discrete link capacities shared by multi-commodity flows, and the lower level problem differentiates the corresponding QoS for demand satisfaction, to prioritize customers and/or commodities. We consider PNDP variants that have either fixed flows (formulated at the upper level) or recourse flows (at the lower level) according to different applications. We transform each probabilistic model into a mixed-integer program, and derive polynomial-time algorithms for special cases with single-row chance constraints. The paper formulates benchmark stochastic programming models by either enforcing to meet all demand or penalizing unmet demand via a linear penalty function. We compare different models and approaches by testing randomly generated network instances and an instance built on the Sioux–Falls network. Numerical results demonstrate the computational efficacy of the solution approaches and derive managerial insights.     

A multiobjective model for maximizing fleet availability under the presence of flight and maintenance requirements

Every aircraft, military or civilian, must be grounded for maintenance after it has completed a certain number of flight hours since its last maintenance check. In this paper, we address the problem of deciding which available aircraft should fly and for how long, and which grounded aircraft should perform maintenance operations, in a group of aircraft that comprise a combat unit. The objective is to achieve maximum availability of the unit over the planning horizon. We develop a multiobjective optimization model for this problem, and we illustrate its application and solution on a real life instance drawn from the Hellenic Air Force. We also propose two heuristic approaches for solving large scale instances of the problem. We conclude with a discussion that gives insight into the behavior of the model and of the heuristics, based on the analysis of the results obtained.