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Integrated Satellite-Navigation for Challenging Environments

适用于具有挑战性的环境的综合卫星导航

基本信息

批准号：
RGPIN-2014-06552
负责人：
Petovello, Mark
金额：
$ 2.48万
依托单位：
University of Calgary
依托单位国家：
加拿大
项目类别：
Discovery Grants Program - Individual
财政年份：
2015
资助国家：
加拿大
起止时间：
2015-01-01 至 2016-12-31
项目状态：
已结题

来源：
https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=589082
关键词：
Integrated Satellite Navigation Challenging Environments

项目摘要

Positioning and navigation information is becoming ubiquitous as automobiles, mobile telephones and even clothing are being equipped with navigation systems/sensors. Most navigation systems rely, at least in part, on Global Navigation Satellite System (GNSS) technology such as the U.S. Global Positioning System (GPS). Unfortunately, GNSS signals that reach the Earth have extremely low power, and system performance degrades in areas where satellite signals are attenuated or obstructed by such things as foliage and buildings. In other scenarios, particularly in urban areas, the satellite signals are reflected prior to being received which limits a receiver’s ability to measure the direct (ideal) distance to the satellite. In both cases, the GNSS receiver cannot track the satellite signals reliably, if at all. This problem can be tackled in two ways: by improving the capability of GNSS receivers, and by integrating GNSS with other sensors. The number and availability of low-cost sensors has increased dramatically in recent years, especially in smart phones and automobiles, and include WiFi radios (and the online data they can access), cameras, light sensors, accelerometers, gyroscopes and magnetometers. The challenge, however, is to determine how to best integrate these sensors with GNSS in order to yield a more accurate and reliable position solution, especially in areas where GNSS is not performing optimally. With this in mind, this project will improve GNSS-based navigation in degraded environments using different approaches by: 1) Enhancing current GNSS receiver performance by using a new architecture where all information from all satellites is used to compute the position. This contrasts with traditional architectures where only a subset of data from each satellite is used to compute a (sub-optimal) position. The result will be more accurate position solutions in more locations, thus enabling more applications. 2) Incorporating 3D building models that are becoming more widely available (e.g., Google Earth). Advanced signal processing methods with GNSS receivers will be integrated with 3D building model data to identify and correct reflected signals that reach the receiver. In this way, instead of only trying to minimize the error from the reflected signal (as is traditionally done), this approach uses the reflected signal in a constructive manner to improve performance. 3) Using an upward-facing camera, such as those found on the front of smart phones, to compute position information and merge this information with GNSS. The research will exploit benefits of an upward-facing camera setup (relative to forward-facing cameras which are more typically used for navigation) to improve vision-based navigation. Also, for the first time, the skyline variability in urban canyons – that is, the outline of the sky that is visible between buildings at a particular location – will be used as a means to determine the absolute position of the user. Later stages of the project will merge these approaches in order to yield optimal performance in a wider range of environments. The algorithms and software developed as part of this project will be of benefit to GNSS receiver manufacturers and to navigation system developers that integrate GNSS with the sensors listed above. With the GNSS-enabled market expected to be worth over $1T (CAD) between 2014 and 2020 this work will help Canada remain a leader in this rapidly growing field. More importantly, the students trained during this research will possess the relevant knowledge and skill to contribute positively to the navigation industry upon graduation.

随着汽车、移动的电话、甚至服装都配备有导航系统/传感器，定位和导航信息正变得无处不在。大多数导航系统至少部分地依赖于全球导航卫星系统（GNSS）技术，诸如美国全球定位系统（GPS）。不幸的是，到达地球的GNSS信号具有极低的功率，并且在卫星信号被诸如树叶和建筑物之类的东西衰减或阻挡的区域中系统性能下降。在其他情况下，特别是在城市地区，卫星信号在被接收之前被反射，这限制了接收器测量到卫星的直接（理想）距离的能力。在这两种情况下，GNSS接收器无法可靠地跟踪卫星信号，如果有的话。这一问题可通过两种方式解决：提高全球导航卫星系统接收器的能力，以及将全球导航卫星系统与其他传感器结合起来。近年来，低成本传感器的数量和可用性急剧增加，特别是在智能手机和汽车中，包括WiFi无线电（以及它们可以访问的在线数据），相机，光传感器，加速度计，陀螺仪和磁力计。然而，面临的挑战是确定如何最好地将这些传感器与全球导航卫星系统结合起来，以便产生更准确和可靠的定位解决方案，特别是在全球导航卫星系统性能不佳的地区。考虑到这一点，该项目将通过以下方式使用不同方法改进退化环境中基于全球导航卫星系统的导航： 1)通过使用一种新的架构来提高当前GNSS接收器的性能，在这种架构中，来自所有卫星的所有信息都用于计算位置。这与传统架构形成对比，在传统架构中，仅使用来自每个卫星的数据的子集来计算（次优）位置。其结果将是在更多位置提供更准确的位置解决方案，从而实现更多应用。 2)简化变得越来越广泛可用的3D建筑物模型（例如，Google Earth）。全球导航卫星系统接收器的先进信号处理方法将与三维建筑物模型数据相结合，以识别和校正到达接收器的反射信号。以这种方式，代替仅尝试最小化来自反射信号的误差（如传统上所做的），该方法以建设性的方式使用反射信号来提高性能。 3)使用向上的摄像头（例如智能手机正面的摄像头）来计算位置信息并将此信息与GNSS合并。该研究将利用面向上的摄像头设置的好处（相对于更通常用于导航的面向前的摄像头）来改善基于视觉的导航。此外，城市峡谷中的天际线变化-即特定位置建筑物之间可见的天空轮廓-将首次用作确定用户绝对位置的手段。该项目的后期阶段将合并这些方法，以便在更广泛的环境中产生最佳性能。作为该项目一部分开发的算法和软件将有益于全球导航卫星系统接收器制造商和将全球导航卫星系统与上述传感器相结合的导航系统开发商。在2014年至2020年期间，全球导航卫星系统市场预计将超过1万亿加元，这项工作将有助于加拿大在这一快速增长的领域保持领先地位。更重要的是，在本研究期间培养的学生将拥有相关的知识和技能，毕业后为航海业做出积极贡献。