New Millimeter-Wave Heterodyne Interferometric Reflectometry Technique for Fast and Accuraate Assessment of Pavement Surface Condition

用于快速准确评估路面状况的新型毫米波外差干涉反射测量技术

• 批准号: 9902024
• 负责人: Chanan Singh
• 金额: $ 18.06万
• 依托单位: Texas A&M Engineering Experiment Station
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 1999
• 资助国家: 美国
• 起止时间: 1999-09-01 至 2003-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=9902024&HistoricalAwards=false
• 关键词: New; Millimeter; Wave; Heterodyne; Interferometric

Texture and Transverse profile measurements of highway surfaces are critical for highway safety. It is the texture which provides skid resistance and the transverse profile that dictates surface drainage. Currently, highway agencies can not measure these properties in real time. High accurancy lasers are under investigation but these are fragile and cost prohibitive for full-scale implementation. The proposed research will focus on the research and development of a new fast, accurate, and low-cost technique for measuring pavement surface characteristics in real time, including transverse profiles, micro and macro textures, and detecting areas of mix segregation in newly constructed asphalt surfaces. This new technology will have a major impact on both safety and new construction quality control. The new technique will be based on the principles of heterodyne, reflectmetry, and interferometry implemented using millimeter waves in the very high frequency range of 90 to 100 GHz. Reflectometry is used in microwaves and optics for reflection measurement. Heterodyne interferometry is used in optics as one of the best methods for accurate measurment of surface roughness of electronic materials. Compared to other technologies, millimeter waves have two uniquely distinct characteristics, which can be explained for accurate non-destructive, non-contact high-resolution surface measurements: higher frequencies and larger absolute bandwidths. These characteristics together can produce systems that have very fine resolution and small size. The proposed technique appears to be the best candidate that can meet all the key specifications required for the pavement problems addressed in this project, namely fast and accurate measurement, very fine resolution, low cost, and small size. There are four major objectives in this research. The first objective is to research and develop a new millimeter-wave profilometer in the frequency range of 90 to 100 GHz. The second objective is to analyze surface reflections and interference patterns. This is needed for accurate data acquisition and processing of the measured results. The third objective is to fabricate various laboratory test specimens needed for the evaluation of the new sensor. The fourth objective is to evaluate the new sensor in both laboratory and field tests. The proposed new technique has not yet been studied and developed for civil engineering applications. It thus not only will provide a unique solution for the pavement surface problems addressed here, but also should open up a whole range of new applications, which have not been feasible with available techniques and systems. Successful research and development of this novel technique for pavement applications will demonstrate feasibility of using millimeter waves in the 90 to 100 GHz range for high-resolution pavement surface measurements, and pave the way for future research and developments of advanced low-cost millimeter-wave sensors for civil engineering applications. The research proposed should therefore have a strong impact on a number of current and future applications of civil engineering.

公路表面的纹理和横向轮廓测量对公路安全至关重要。它是提供防滑性的纹理和决定表面排水的横向轮廓。目前，高速公路机构无法实时测量这些属性。高精度激光器正在研究中，但这些激光器很脆弱，而且对于全面实施来说成本过高。该研究将重点研究和开发一种新的快速、准确、低成本的技术，用于实时测量路面特征，包括横向轮廓、微观和宏观纹理，以及检测新建沥青表面的混合料离析区域。这项新技术将对安全和新建筑质量控制产生重大影响。这项新技术将基于外差、反射测量和干涉测量的原理，利用90至100 GHz的高频毫米波实现。反射计用于微波和光学的反射测量。外差干涉法是光学领域精确测量电子材料表面粗糙度的最佳方法之一。与其他技术相比，毫米波有两个独特的特点，这可以解释为精确的非破坏性、非接触式高分辨率表面测量：更高的频率和更大的绝对带宽。这些特性结合在一起可以产生分辨率非常高、尺寸很小的系统。所提出的技术似乎是满足该项目中所解决的路面问题所需的所有关键规格的最佳候选技术，即快速准确的测量、非常精细的分辨率、低成本和小尺寸。本研究有四个主要目标。第一个目标是研究和开发一种新的频率范围为90至100 GHz的毫米波剖面仪。第二个目标是分析表面反射和干涉模式。这是需要准确的数据采集和测量结果的处理。第三个目标是制作评估新传感器所需的各种实验室测试标本。第四个目标是在实验室和现场测试中评估新的传感器。提出的新技术尚未研究和开发用于土木工程应用。因此，它不仅将为这里讨论的路面问题提供独特的解决方案，而且还将开辟一系列新的应用，这些应用在现有的技术和系统下是不可行的。这项新技术在路面应用中的成功研究和开发将证明在90至100 GHz范围内使用毫米波进行高分辨率路面测量的可行性，并为未来用于土木工程应用的先进低成本毫米波传感器的研究和开发铺平道路。因此，拟议的研究应该对土木工程的一些当前和未来的应用产生强烈的影响。