高铁移动网络覆盖是国内三大通信运营商的一个重点,而高铁隧道内移动网络覆盖更是运营商的一大难点痛点。文章根据我国中部省份某高铁线路覆盖规划实例,采用“设备+POI+泄漏电缆”模式,即三家运营商信号源设备通过同一POI(point of interface,多系统接入平台)接入,信号输出到泄漏电缆进行隧道覆盖,隧道口场坪站安装宽频切换天线对隧道外进行延伸覆盖,通过链路预算合理布置各运营商主设备信号源,从而实现隧道到室外的无缝覆盖。最后,根据已有成熟网络覆盖解决方案,对未来5G高铁隧道移动网络覆盖方案进行了探讨。 相似文献
In the last decade we have witnessed a rapid growth of Humanoid Robotics, which has already constituted an autonomous research field. Humanoid robots (or simply humanoids) are expected in all situations of humans’ everyday life, “living” and cooperating with us. They will work in services, in
homes, and hospitals, and they are even expected to get involved in sports. Hence, they will have to be capable of doing diverse
kinds of tasks. This forces the researchers to develop an appropriate mathematical model to support simulation, design, and
control of these systems. Another important fact is that today’s, and especially tomorrow’s, humanoid robots will be more
and more humanlike in their shape and behavior. A dynamic model developed for an advanced humanoid robot may become a very
useful tool for the dynamic analysis of human motion in different tasks (walking, running and jumping, manipulation, various
sports, etc.). So, we derive a general model and talk about a human-and-humanoid simulation system. The basic idea is to start
from a human/humanoid considered as a free spatial system (“flier”). Particular problems (walking, jumping, etc.) are then
considered as different contact tasks – interaction between the flier and various objects (being either single bodies or separate
dynamic systems). 相似文献
Camera calibration is the first step of three-dimensional machine vision. A fundamental parameter to be calibrated is the position of the camera projection center with respect to the image plane. This paper presents a method for the computation of the projection center position using images of a translating rigid object, taken by the camera itself.
Many works have been proposed in literature to solve the calibration problem, but this method has several desirable features. The projection center position is computed directly, independently of all other camera parameters. The dimensions and position of the object used for calibration can be completely unknown.
This method is based on a geometric relation between the projection center and the focus of expansion. The use of this property enables the problem to be split into two parts. First a suitable number of focuses of expansion are computed from the images of the translating object. Then the focuses of expansion are taken as landmarks to build a spatial back triangulation problem, the solution of which gives the projection center position. 相似文献
