共查询到17条相似文献,搜索用时 78 毫秒
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简要介绍了手持电脑和Windows CE操作系统的特点.以CMC SuperStar GPS OEM板为例,讨论了在二进制和NMEA-0183两种格式下对GPS OEM板设置时的指令格式,详细介绍了利用Windows API函数对手持电脑的串口进行操作的方法,实现了在Windows CE环境下对GPS OEM板进行设置和导航定位数据及时间信息的提取与处理等功能. 相似文献
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Windows CE下实现掌上机和GPS OEM板的通信 总被引:3,自引:0,他引:3
简述了WindowsCE的特点,详细介绍了如何利用WindowsAPI对掌上机串口进行通讯操作,实现了在Windows CE下对GPS OEM板数据的读取,该通讯方法适用于各种条件尤其是在野外条件下的作业。 相似文献
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简单介绍了GPS接收机串口通信的基本概念和GPS数据输出的格式。主要论述了如何用多线程编程方法在Windows CE下实现GPS接收机与PDA的通信,以及线程间的数据通信,线程调度,数据同步等问题。 相似文献
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首先介绍了系统开发环境,系统采用EVC基于Windows CE进行开发;接着介绍了ADO对象与ADOCE对象的异同点、Windows CE平台下的数据存储格式、数据库开发环境的配置;最后,文章讨论了车辆导航系统中如何利用ADOCE访问Access数据库实现地物查询. 相似文献
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手持GPS因为体积小、携带方便、操作简单,在地质测量中已得到广泛的应用,根据近几年的工作实践,论述了在地质测量方面手持GPS的具体应用以及精度分析、使用方法、坐标格式设置和作业流程. 相似文献
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GPS接收机的核心器件即为GPS OEM板(即GPS芯片),对其直接进行开发,在使用上具有灵活方便、经济实用、便于融合等优点。本文以Motorola M12MT+TIMING ONCORE型GPS OEM板为例,论述了GPS OEM板的具体开发使用过程和相关注意事项,并对其授时性能、1pps(秒脉冲)输出的特点等进行了研究,提供了用其实现精确授时的方法,并对授时精度进行了分析,对于测量中精确数字授时的实现具有一定的实际意义。 相似文献
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介绍GPS接收机数据的RINEX标准交换格式,讨论二进制数据格式文件向文本文件转换的方法及需要注意的问题,通过分析HemisphereJ、avad、AC12、NavCom 4种不同OEM板二进制数据格式,指出GPS接收机的二进制数据文件向RINEX文件转换的一般方法,并编程实现所有程序,验证方法的正确性。 相似文献
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GPS数据采集软件的实现 总被引:2,自引:0,他引:2
利用C#.NET和Superstar Ⅱ OEM板,开发一套GPS数据采集软件。本软件能够动态显示各可视卫星的卫星号、信号强度及空间分布;以北纬、东经、海拔高度表示的三维定位结果及描述几何拓扑误差的HDOP、PDOP、VDOP等误差放大因子;生成动态存储NMEA--0183原始语句及其数据提取结果的文件,为今后分析接收机性能,确定GPS数据采集时段、采集位置,进行定位结果的优化处理等方面提供数据源。 相似文献
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The EGNOS service will provide better positioning availability and accuracy than that from the standalone GPS solutions. However,
in order to access the EGNOS service, the end user needs to access the corresponding GEO satellites that broadcast the augmentation
information for the region. This is not a problem normally for aviation and maritime applications because an open sky is always
available for such applications. However, an open sky is not always available for land applications because of the obstacles
in the vicinity of the end users, for example, in the city canyons. The situation gets worse for the regions at high latitudes
because the elevation angles to the GEO satellites are rather low (e.g. 4–22° in Finland). This article describes briefly
the SISNeT technology, designed and developed by the European Space Agency, which allows accessing the EGNOS SIS via the Internet.
It will describe in detail the handheld SISNeT receiver, designed and developed by the Finnish Geodetic Institute under ESA
contract. The SISNeT data server is an IP-based server that acquires the EGNOS messages from an EGNOS receiver, and broadcasts
them over the Internet in real-time. The handheld receiver consists of a GPS PC-card receiver, a GPRS (or GSM) card phone,
and a pocket PC as the host platform. The receiver software is a Windows CE-based package with a multi-process and multi-thread
architecture. It simultaneously receives: (1) the EGNOS SIS over a GPRS wireless connection and the Internet and (2) the NMEA
messages from a serial connection to a GPS receiver. It decompresses and decodes the EGNOS messages, and utilizes the information
in the messages to estimate the EGNOS-corrected coordinates, which are finally delivered to the end user via a virtual COM
port. The virtual COM port has been implemented as a stream interface driver in the Pocket PC. It can be accessed in the same
way as the physical COM port in a GPS receiver is accessed. Therefore, it is easy to interface to any third-party applications.
The test results show that the handheld SISNeT receiver can provide a positioning accuracy of about 1–2 m for the horizontal
components, and 2–3 m for the vertical component in real time. Due to the poor performance of the wireless connection, 10–30%
of the EGNOS messages can be lost depending on the services provided by the wireless network operators. The impact of the
messages lost on the positioning accuracy is about 0.5 m in both the horizontal and vertical components.
Electronic Publication 相似文献