利用地理信息系统定位监测的GSM基站研究(IJCNIS-V5-N8-5)
I. J. Computer Network and Information Security, 2013, 8, 39-45
Published Online June 2013 in MECS (https://www.wendangku.net/doc/db9111696.html,/)
DOI: 10.5815/ijcnis.2013.08.05
GSM Base Stations Location Monitoring using Geographic Information System
Kuboye B. M., Dada O. A., Akinwonmi F. C.
School of Sciences, Federal University of Technology, Akure, Nigeria
kubonline@https://www.wendangku.net/doc/db9111696.html,, abisoyedada@https://www.wendangku.net/doc/db9111696.html,, shadian2003@https://www.wendangku.net/doc/db9111696.html,
Abstract—Global System for Mobile Communication (GSM) is a digital system developed to meet the desires of the entire public. As the population of a particular area, city or country increases, the number of mobile subscribers increases too. GSM network operators have to reduce congestion on their networks in order to satisfy their subscribers, therefore, a means of monitoring the base stations’locations and the geographical area of where they are located are important factor to achieve this purpose. This work provides a simple step-by-step approach on how to monitor the location of the base stations. A review of GSM and Global Positioning System (GPS) technology and their applications to the Geographic Information System (GIS) are presented. The means of taken the coordinates of base stations using a GPS device is also presented. ESRI’s ArcView application software was used to design the map that shows the location of the base station and thereafter was integrated into the web. It concluded with the recommendation to GSM operators in Nigeria. If the recommendations are given necessary attention, the planning and optimization of cell sites will be enhanced and thereby reduce congestion on network. As a result, the performance of Network will improve, and it will give rise to subscribers’ satisfaction and increasing profit returns to the operators.
Index Terms—GIS, GPS, GSM, Base station, Subscriber
I. INTRODUCTION
The goal of development of wireless system is to enable communication everywhere and at any time. The success experienced so far in telecommunication have depended on the progress made in the areas of communication systems, microletronics, software and hardware technology, security and signal processing. The most popular of all the current wireless systems is Global System for Mobile Communication (GSM) where there is roaming freedom within and across networks. Also, communication everywhere with everybody is possible except for people who are in the rural areas where there is still no GSM coverage.Geographic Information System (GIS) integrates hardware, software, and data for manipulating all forms of geographically referenced information. It provides the framework for all forms of spatial data storage, retrieval, analysis, display, reporting and modeling [1]. Geographic Information System is used to process maps of one type or another. An individual map contains a lot of information which is used in different ways by individuals or organizations [2]. These maps are used in diverse applications, ranges from locating telephone wires and water distribution pipelines to displaying the extent of deforestation in a region. The traditional maps are static, therefore, difficult and expensive to keep to date. Also, maps exist as separate sheets and the use of the map depends on the coverage. The complexity of the map often requires experts to extract data of interest for specific purpose [3]. GIS technology has cut attention of professionals because of its capability to incorporate graphical features with tabular data to measure real world problems. GIS helps planners analyze problems quickly and thoroughly to enable them formulate solutions that will achieve long-term goals [1].
The GSM has become one of the wireless technologies that has direct impact on people and as a result has gained acceptance by everyone. At present, wireless operators are trying to have higher level of network efficiency to gain the acceptance of customers. Geographic Information Systems (GIS) is now used by wireless operators to ensure their businesses operate at high efficiencies. A huge crowd from different parts of Nigeria are always gathered during many festivals like the Osun-Oshogbo festival, the Sokoto annual horse race event, the Argungu fishing festival. Most cities in Nigeria especially state capitals normally experienced a population surge due to rural urban drift. Most of these state capitals have opportunities that are not present in sub-urban areas. As a result, there must be a way of knowing the location of base stations, their distance to each other, so that when the need of having more base station arises, there will be proper dimensioning and all subscribers in all the locations will have fair and proper connections.
II. METHODOLOGY
In order to design and develop a basic web-enabled Geographic Information System for locating MTN base
40GSM Base Stations Location Monitoring using Geographic Information System stations in Akure North and South Local government,
various methodologies were reviewed to have
information for the design of the system. Personal tour
of the MTN base stations in Akure North and South
Local governments, to get the GPS coordinates were
done. The GIS maps downloaded from Google Earth
and the GPS coordinates taken for MTN Base Stations
were analysed. Thereafter, ESR I’s Arc view software
was used to convert the maps to raster maps for
digitalization. The coordinates were then inserted on
the digitized map. The raster map and the digitized
map showing the MTN base stations were linked to the
website which was designed with PHP and HTML. The
results were analysed, then the conclusion and the
recommendations were drawn.
III. SYSTEM REVIEWS
A. Global System for Mobile Communications
(GSM)
The GSM was developed to create a common
European mobile telephone standard but has been
accepted all over the world. Discussions were held
between 1982 to 1985 to decide either to build an
analog or digital system. Upon several field tests, a
digital system was adopted for GSM. The narrowband
time division multiple access and frequency division
multiple access (TDMA/FDMA) solution was chosen in May 1987 [4].
GSM has been standardized to use 900MHz, 1800MHz, and 1900 MHz radio band which is normally called the frequecy of the network [5]. The 900MHz and 1800 MHz used the same base-band signals, but operate on different carrier frequencies. The radio frequency separation between the matching uplink and downlink carrier for 900MHz is 45MHz while that of 1800MHz is 90 MHz as seeing in fig 1[4].
The GSM network is made up of geographic areas. As shown in Fig. 2., these areas include cells, location areas (LAs), MSC/VLR service areas, and public land mobile network (PLMN) areas. A cell is the coverage area of a given radio by one base transceiver station. The GSM network identifies each cell via the cell global identity (CGI) number assigned to each cell. The location area (LA) is a group of cells and subscribers are paged in the area. One or more base station controllers serve each LA, but with a single MSC (see Fig.1). Each LA is assigned a location area identity (LAI) number. An MSC/VLR service area represents the part of the GSM network that is covered by one MSC and which is reachable, as it is registered in the VLR of the MSC [6].
Figure 2.PLMN Service Area(Source:[6])
The PLMN Network is an area served by one GSM operator. The GSM subsystem consists of three major components and they are Mobile station (MS), Base Station System (BSS) and Switching System (SS) as shown fig. 3.
Figure 3. GSM Network Subsystems (source: [7]) The Mobile station consists of Mobile Equipment (ME) (mobile phone) and Subscriber Identity Module (SIM). SIM provides personal mobility so that subscriber can have access to subscribed services irrespective of a specific ME [7]. SIM has a microprocessor and memory that holds information on the chip even if the SIM card is deactivated [5]. SIM is stored inside the ME to identify each subscriber on the GSM Network through International Mobile Subscriber Identity (IMSI) number.
A GSM network is comprised of many base station subsystems (BSSs). The BSS consists of base station controllers (BSCs) and the base transceiver stations (BTSs). The BSS performs the necessary functions for monitoring radio connections to the Mobile Station (MS), coding and decoding voice, as well as, rate adaptation to and from the wireless network. The
Downlink Channel BS
covered area of a cellular network is divided into smaller areas called cells. Each cell is connected to a base station system, which communicates simultaneously with all mobiles within the cell, and passes traffic to the Mobile Switching Center. The Base Station System is connected to the ME via a radio interface [8].
The central component of the Network switching subsystem (SS) is the Mobile Switching Center (MSC). MSC is the link between the Base station subsystem and network switching subsystem of the GSM Network (Fig 5). Also it acts as the link between the cellular system and the PSTN. MSC is responsible for performing call routing to a roaming subscriber, registration, authentication, location updating, handovers and subscriber-related functions [7]. These services are provided in conjunction with several functional database entities, which together form the Network switching system. The databases are home location register (HLR), visitor location register (VLR), authentication center (AUC), equipment identity register (EIR), group call register (GCR), message center (MXE), mobile service node (MSN), and short message center (SMSC). Signaling between functional units in the MSC uses signaling system number 7 (SS7). SS7 is widely used for trunk signaling in the ISDN and in public networks. [7]. Signaling allows different functional units to interwork successfully and provide a data communication path between network nodes [9]. GSM subscribers could be anywhere within the network when they make call, the MSC must ensure that the calls are routed to the appropriate destination. In other to simplify this network management function, the entire PLMN network is divided into service areas and each service area is allotted one MSC to monitor the activities. MSC are interconnected to monitor the movement of subscribers. Some MSC are called gateway MSC (GMSC). A gateway is a node used to interconnect two networks. The GMSC is the interface between mobile network and other mobile network or any other network. All incoming calls to the PLMN from another PLMNs, fixed wireless or landlines must pass through the gateway. Gateway MSC works as an incoming transit exchange for the GSM/PLMN. Gateway MSC contains interconnecting functions to make interconnections between two PLMNs, PSTN or fixed wireless system. They also route incoming calls to the proper MSC within the Network [10]. In summary, the role of MSC is to manage the communications between the GSM users and other telecommunication users.
B.Global Positioning System (GPS)
The Global Positioning System (GPS) is a space-based global navigation satellite system (GNSS) that provides reliable location and time information in all weather and at all times and anywhere on or near the Earth when and where there is an unobstructed line of sight to four or more GPS satellites [11]. GPS consists of three segments: the space segment, the control segment, and the user segment as seen in fig. 4. The Space segment has 24-satellite constellation. Each GPS satellite transmits a signal, which has a number of components, namely, two sine waves called carrier frequencies, two digital codes, and a navigation message. The digital codes and the navigation message are added to the carriers as binary bi-phase modulations [12]. The carriers and the codes are used mainly to determine the distance from the user’s receiver to the GPS satellites. The navigation message contains the coordinates of the satellites as a function of time.
The main function of the operational control segment is to track the GPS satellites in order to determine and predict satellite locations, system integrity, and other important information [12]. The information is then packed and uploaded into the GPS satellites through the S-band link. The User segment includes all categories of users. Users receive the GPS signals on the GPS receiver to determine his or her position anywhere in the world. GPS is available to all users around the world at no cost.
Figure 4. GPS Segments (source: [12])
C.Geographic Information System (GIS)
GIS is a system for capturing, storing, checking, integrating, manipulating, analysing and displaying data related to positions on the Earth's surface [2]. GIS is also defined as a modern technological tool for effective and efficient storage, retrieval and manipulation of spatial and non-spatial data for deriving scientific, management and policy making information [1]. Typically, Geographical Information System is used for handling maps of one kind or another. These might be represented as several different layers where each layer holds data about a particular kind of feature. Each feature is linked to a position on the graphical image on a map and a record in the attribute table [13].
D. GPS and GIS Integration
Spatial or geographic data can be obtained from a variety of sources such as existing maps, satellite imagery, and GPS. GPS is used to collect the GIS field data in a digital format in either real-time or post processed mode. Since GIS can accept geographic data
from a variety of sources, once the information is collected, it is stored as a collection of layers in the GIS database. Afterwards, GIS is used to analyze the data in order to take meaningful decisions.
IV. RELATED WORK
Some researches related to the use of GIS have been done and presented in literatures. A research based on the application of GIS in tourism in Nigeria was presented [14]. It discusses how a web-based GIS can be used to gather and analyse the data regarding tourisms for efficient management and promotion in Nigeria. Ajala described how MTN Nigeria Communication is using GIS capabilities with GSM network monitoring tools to find areas where subscribers are having low quality signals [15]. A recent work was published by Fosu describing how GIS technology can enhance revenue mobilization in the local government [1]. The work describes comprehensively the functionalities of GIS application software developed for local authorities in Ghana for internal revenue mobilization. The work clearly shows how an integrated GIS database technology tool is capable of providing a more efficient means of collecting, tracking and managing of Local Government revenue. Another work demonstrated how GIS can be used to optimize GSM system using measurement report (MR) [16]. The MR is a report from cell that shows the number of mobile station (MS) connected. The report is sent to the cell every 480s so as to show that the MS sees the BTS and base transceiver station (BTs) sees the MS. This MR is then integrated into the cellular office database which is connected to the GIS software to serve as points’location for all MS connected to the cell. This work enables the GSM operator to know the MS distribution, in other words, the distribution of subscribers within the cell.
Vincezo Barrile [17] use investigated with the help of GIS whether the fixed installations for cellular phone is compatible with the health of citizens and check if the values of exposures to electromagnetic fields produced by them are within the limits set by law [17]. This was realised by using GIS to store, manage, and process all data relating to the electromagnetic fields produced by the antennas of all the installed cellular infrastructures within the city. The result will help the operators to know how to plan the installation of their infrastructures to avoid health risk to people. A novel analysis method for analysing the cell coverage in GSM network employed GIS system in carrying out the work effectively [18]. The method involves collection and analysis of mobile measure data from the operation and maintenance center (OMC) system of the MSC. Thereafter, cell coverage chart was drawn using GIS software and the problem cells which have deviated from the coverage were identified on the graph.
V. METHODS OF DATA ACQUISITION The data used in this work were collected through the use of GPS that captures the coordinates in terms of longitudes and latitudes of the base stations in Akure North and South local governments of Ondo state, Nigeria. Thereafter, Google earth was used to capture the area views of the two local governments. Google Earth displays satellite images of varying resolution of the Earth's surface, thus, allowing users to see things like cities and houses looking perpendicularly down or at an oblique angle. It allows users to search for addresses of cities, towns in a country using coordinates of the area to be visited. The satellite image of some parts of Akure from Google Earth’s is shown i
n Fig. 5.
Figure 5. A part of Akure as shown in Google Earth
A.Geo-referencing and Mosaicing of Images Georeferencing deals with the definition of existence of something in physical space, that is, to establish its location in terms of coordinate systems. The term is used when establishing the relationship between raster or vector images and coordinates. It is also use to determining the spatial location of other geographical features. The four specific control points for the geo-referencing on the image with a yellow pin on each point are shown in Fig. 6. At each point, the coordinate (longitude and latitude) was taken. These images are then imported to ESRI’S Arc View for geo-referencing. Thereafter, the images were mosaiced, that is, small different images were joining together so as to get the target image. The Imagine Analysis tool in ESRI’s Arc View helped to link the images together. In the process of capturing images, the images are saved
in such a way that they overlap each other. This overlap helps in the joining of all the available images smoothly into one whole image as shown in Fig. 7.
Figure 6. A Georefenced Image of a part of Akure
Figure 7. A Mosaic Image of a part of Akure
B. Creating the digitized map
The boundary of Akure North and South local governments was carved out from the mosaic image and then converted to shape files using the query builder as shown in Fig. 8.
Figure 8. Digitized map of Akure
C. GIS - Base station GPS location integration
The coordinates of the base stations that were collected using GPS tool were exported to ArcView to form the attribute table. These coordinates were then added as an event theme. As soon as event theme was added, the coordinates that were activated immediately transforms to the locations of base stations on the map as shown in Fig. 9. The map clearly shows the location of all the base stations of MTN in Akure north and south local governments of Ondo state, Nigeria as taking by the GPS system.
Figure 9. A Layout of digitized map of Akure
VI. WEB IMPLEMENTATION AND
INTERPRETATION
The digital map of Akure North and South local governments showing the locations of the MTN base stations are integrated into the web as shown in fig. 10 and fig. 11. The essence is to make the base station locations accessible through Internet. If there is any complain of congestion or poor signals in any part of the coverage area by the subscribers, both the subscribers and the operators can know the location of the base station and the nearby base stations. Also, it will also help the operator to validate the complains of the subscribers and will to know if there is will be need of optimization of the base stations or erected of new one. The poor signal might be as a result of long distance of subscribers who have just moved into the area from the available base station. On the other hands, if it is congestion, it might result from surge in the number of people living the area thereby making the infrastructures of the base stations insufficient for them.
Figure 10. Digitized Ondo state map
Figure 11. Digitized Akure map
VII. CONCLUSION
GSM is designed to meet the needs of the entire public. As the population of a particular area, city or country increases, the number of mobile subscribers increases too. For any GSM network provider to have optimum profit returns, they must find all means of satisfying their subscribers. This work has shown how GSM operators can easily monitor and locate their Base stations. Also, they will know how population increases by using the Google map to know when some areas are inhabited by people.
VIII. RECOMMENDATION
It is very thereby recommended for GSM network provider to have a this type of systems in other to have proper dimensioning of their network at any point in time.
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O. A. Dada, born in 1985. B.Tech. in the Federal University of Technology, Akure from Nigeria. Her main research interests include Wireless communication and Geographical Information System applications.
F. C. Akinwonmi, born in 1973. M.Tech. candidate in the Federal University of Technology, Akure from Nigeria. Her main research interests include Computer Security and Geographical Information System Applications.
B. M. Kuboye, born in 1971. Ph.D. and lecturer in the Federal University of Technology, Akure from Nigeria. He is member of the Nigeria Computer Society. His main research interests include Computer and Wireless Networks Communication and Geographical Information System.
基站故障处理流程规范
基站故障处理流程规范 1.概述 1.1 编制背景 为进一步规范移动基站处理流程,及时处理基站发生的故障,保证基站故障设备能够在最短时间得以恢复及对网络指标的影响降到最低,特制定基站故障抢修指导手册,以便基站维护人员发现、处理、分析故障问题提供参考。 1.2 编制单位 中国移动通信集团江西有限公司鹰潭分公司网络部 1.3 指标要求 按照基站维护服务技术规范书的要求,基站维护人员在接到设备障碍通知后,应及时到现场处理。 1.4 处理原则 1.维护人员应按“先室内,后室外,先软件,后硬件”的原则进行故障处理 工作,即在排除电力、光缆中断的因素后,再进入基站处理故障,在排除 软件吊死、数据丢失等软件原因后,再对调、更换硬件。 2.在充分了解故障信息的情况下,尽量缩短故障处理时长,更换需更换且 仅需更换的板件。因此,接到故障通知后,应根据通知内容对故障进行 预判断,以便采取针对性的处理措施,定位真正的故障点,避免错误信 息误导,延长故障恢复时间。 3.维护人员在故障处理过程中,需协调其它部门或单位解决问题时,应立 即展开协调并向上级报告相关进展情况。 4. 对载频,主控板,传输板等故障处理应禁止在网络指标考核 (8:00-11:00,18:00-20:00)时段进行处理
2. 故障处理流程
3. 基站故障分类及参考处理步骤 3.1基站载频退服 步骤1:先要求机房查看载频信令是否激活,即是否处于WO状态。如果载频信令没办法激活或已激活,整个BCF也已重启,但载频依然退服,则带上对应型号的载频。 步骤2:到站后,若扇区没开跳频,则闭掉一块正常工作的载频,将故障板件和它对调。若扇区开了跳频,则先叫机房闭站。 步骤3:对调后,重新集成,观察载频是否能正常工作,如果故障随着载频走,则用新板更换故障载频;如果故障依然存在原位置,则可能与载频硬件无关,需重新定位故障点。 步骤4:故障恢复后,处理板卡标签和固定资产变动,签好出入登记本以及故障处理记录,离开基站。 3.2基站因停电退服 步骤1:维护人员接到停电通知后,首先需询问当地电力公司,看该基站附近是否在做电力抢修,如果电力公司确定是在做电力抢修,详细了解将停电时长及恢复供电时间。 步骤2:在得到确切的时间后,根据基站固定资源调查表,或平时巡检表的信息,判断电池组的持续供电时间,如果电业局确定能恢复供电的时间很短,远小于电池组的安全供电时间,则不必带油机前往基站发电,但需每隔1小时跟踪一次供电恢复情况。如果电池组不能或勉强能撑到交流供电恢复时间,则需立即带上小油机去站上发电。 步骤3:根据基站的配置选定功率匹配并已经过检测完好的油机和电缆线,备足燃油和工具(万用表、钳形表、电笔、绝缘胶布以及其他常用工具)及时到达市电故障的基站。 具体油机选定方法举例如下:某基站通信设备直流负荷为45A(空调、照明除外),配置 GFM400Ah/48V蓄电池2组,开关电源为48V电源,基站由三相交
环境监测空气废气现场采样技术要求采样流量等
用X光看片机检查每张滤膜不得有针孔或缺陷,在15~30℃任一点条件下,滤膜在干燥器中平衡24h,称重。 将已编号并称重滤膜绒面向上,放在滤膜支持网上,放上滤膜夹,对正,拧紧,使不漏气。 样品采完后,打开采样头,用镊子轻轻取下滤膜,采样面向里,将滤膜对折,放入号码相同的滤膜带中。 样品采完后,尘膜在恒温箱中,与干净滤膜平衡条件相同温度、湿度、平衡24小时。 滤膜称量精确到。
空气:Saltzman法: 短时间采样(1h以内):10ml吸 收液(5g对氨基苯磺酸)乙二胺 盐酸盐)大气综合采样器 长时间采样(24h以内):或50ml 吸收液液柱不低于80mm,采气时 吸收液温度保持在20±4℃,空 气采样器采样、样品运输和存放过程中时应避光。气温超过25℃时,长时间运输及存放样品应采取降温措施。 空气中臭氧浓度超过m3,采样时在吸收瓶入口端串联一段15~20cm长的硅胶管,不干扰NO2测定水平。
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GIS在资源环境领域中的应用(一)
GIS在资源环境领域中的应用(一) 摘要:结合地理信息系统(GIS)和资源环境的特点,阐述了地理信息系统在林业、农业、及土地资源领域中的应用,并对GIS在资源领域的发展趋势做了简要论述。 关键词:地理信息系统;资源;环境 1引言 地理信息系统(GIS)是一种兼容存储、管理、分析、显示与应用地理信息的计算机系统,是分析和处理海量地理数据的通用技术。GIS以其强大的空间数据管理系统、形象直观的应用界面、强大的空间分析能力等特点,能为现实地理空间上的物质和能量运动规律的研究提供方便、准确的管理和空间分析手段。因此,GIS与环境科学的结合运用有着巨大的发展潜力。GIS与环境科学在研究对象和研究方法上所具有的相似性和互补性,使二者的结合孕育着巨大的发展潜力,预期在环境管理、环境监测、环境规划、环境影响评价、环境工程及环境地球化学等领域拥有广泛的应用前景。 2GIS在农业中的应用 在我国,从20世纪80年代中期开始,GIS技术就被应用于农业领域,从国土资源决策管理、农业资源信息、区域农业规划、粮食流通管理与粮食生产辅助决策到农业生产潜力研究、农作物估产研究、区域农业可持续发展研究、农用土地适宜性评价、农业生态环境监测、基于GPS和GIS的精细农业信息处理系统研究等,都取得了很大的成绩,一些研究成果直接应用于农业生产,取得了很大的经济效益。随着GIS理论的产生发展以及方法和技术的成熟,在农业领域的应用也逐步深入。从技术角度看,GIS在我国农业资源与环境领域中的应用进展主要体现在四个方面: (1)作为农业资源调查的工具,建立了农业资源地理数据库,实现空间数据库的浏览、检索等,利用GIS绘制农业资源分布图和产生正规的报表。 (2)作为农业资源分析的工具,GIS技术已不限于制图和空间数据库的简单查询,而是以图形及数据的重新处理等分析工作为特征,用于各种目标的分析和重新导出新的信息,产生专题地图和进行地图数据的叠加分析等。 (3)作为农业生产管理的工具,主要是建立了各种模型和拟订各种决策方案,直接用于农业生产。 (4)作为农业管理的辅助决策工具,利用了GIS的模型功能和空间动态分析以及预测能力,并与专家系统、决策支持系统及其它的现代技术(如RS和GPS)有机结合,便于我国农业生产的管理和辅助决策。 3GIS在林业中的应用 林业生产领域的管理决策人员面对着各种数据,如林地使用状况、植被分布特征、立地条件、社会经济等许多因子的数据,这些数据既有空间数据又有属性数据,对这些数据进行综合分析并及时找出解决问题的合理方案,借用传统方法不是一件容易的事,而利用GIS方法却轻松自如。 社会经济在迅速发展,森林资源的开发、利用和保护需要随时跟上经济发展的步伐,掌握资源动态变化,及时做出决策就显得异常的重要。常规的森林资源监测,从资源清查到数据整理成册,最后制定经营方案,需要的时间长,造成经营方案和现实情况不相符。这种滞后现象势必出现管理方案的不合理,甚致无法接受。利用GIS就可以完全解决这一问题,及时掌握森林资源及有关因子的空间时序的变化特征,从而对症下药。 林业GIS就是将林业生产管理的方式和特点溶入GIS之中,形成一套为林业生产管理服务的信息管理系统。以减少林业信息处理的劳动强度,节省经费开支,提高管理效率。 GIS在林业上的应用过程大致分为三个阶段,即: (1)作为森林调查的工具:主要特点是建立地理信息库,利用GIS绘制森林分布图及产生正规
基站调测知识
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爱立信 WCDMA 基站常见告警处理方法
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简析环境监测现场采样中的质量控制
简析环境监测现场采样中的质量控制 发表时间:2017-10-09T12:29:53.203Z 来源:《基层建设》2017年第14期作者:刘洋 [导读] 摘要:现场采样是环境监测工作的重要基础工作,而现场采样在环境监测过程中处于基础和核心位置,是环境监测活动的初始阶段。 深圳市宝安区环境监测站广东深圳 518101 摘要:现场采样是环境监测工作的重要基础工作,而现场采样在环境监测过程中处于基础和核心位置,是环境监测活动的初始阶段。因此,环境监测工作中一定要严格根据相应的采样标准以及要求执行,不断加强环境监测现场采样质量管理工作,确保环境监测结果的真实可靠性、准确性。为此,本文主要分析了环境监测现场采样质量控制的相关措施,以期提高其采样质量。 关键词:环境监测;现场采样;分析方法;样本保存;质量控制 一、环境监测样品出现误差的原因分析 环境监测是一个由多个环节组成的有机系统,而现场采样是进行环境监测的基础一步。如果不能保证采样数細代表性和准确性,即使后期处理手段和处理方法如何可靠,都不能精确反映需要监测的环境的数据指标。因此,本文接下来主要分析了样品出现误差的原因: 1、自然因素 在环境监测现场采样工作开展的过程中,自然因素是非常重要的因素,自然因素是在不断变化的,所以,在自然环境中进行样品的采集很易受到影响。比如环境温度、风速、雨雪等一系列的因素都会给自然环境中污染物分布造成一定的影响,所以,在采样地表水的时候,若是监测采样和河岸的距离比较近,那么可能会导致较大误差的出现,并且,随着季节的不断变化,河道涨潮的时间也是各不相同的。 2、准备工作不完善 采样前的准备工作不足和监测点布置不合理,采样准备工作包括制定监测方案、确定监测对象、实验仪器准备和环境保护措施等,检测点的布置应遵循一定的随机性和不确定性原理,目的在于最大程度上反应需检测区域真实的环境质量。但当前采样准备工作不甚合理,存在采样监测计划不详细、现场采样人员不清楚采样点位周围情况,不熟悉采样方法、样品保存、现场测定技术和采样过程中的安全保证措施等工作,导致采集的环境样品缺乏真实性、代表性和完整性。 3、采样容器 环境监测采样需要利用专门的容器,如果所选容器不当,导致样品与容器间产生物理、化学反应,如光解、溶解等,均会影响环境监测数值的准确度。为降低此类因素的影响,需要选择性能稳定的容器,并保证容器表面清洁,避免样品与各类物质产生反应,从而影响样品监测准确性。 4、采样频率及定位 在进行环境监测采样时,采样频率对环境污染情况有直接影响。采样的时间选择、排污时间的安排等与时间有关的因素,都会影响环境监测样品采集的代表性与准确性。即使是处于相同的环境之下,不同地点、位置的环境情况也会有所不同。同时,对于具有相同性质的监测对象来说,如果他们处于不同的监测环境中,其选择的采集地点也是不同的。 二、水质采样 1)选择不同方式进行分析。在开展环境监测工作的时候,是否运用了正确的分析方式,会直接影响监测结果的准确性和科学性,监测样本相同,因为来源形式存在较大的差异,导致采取分析方法也存在比较大的不同,所以,应该根据监测项目在污水或者是水体中的浓度水平以及具体的执行标准进行确定,选择最合适的监测方式,检出限应该比执行标准值的五分之一低,从而达到样本监测的最基本要求。在进行方法选择的时候,首先应该全面的考虑到抗干扰能力,比如采样工作人员应该全面的了解其所采集样本本身的性质。比如,我国有些化工企业在生产的时候,生成的废水本身便是高氯废水,在开展废水监测相关工作的时候,采集的COD样品时需要明确标准监测分析通过氯气校正方式进行,这样得到的监测结果才可能有效和准确。 2)环境影响因素。在环境监测现场采样工作开展的过程中,自然因素是非常重要的因素,自然因素是在不断变化的,所以,在自然环境中进行样品的采集很难不受到影响。比如环境温度、风速、雨雪等一系列的因素都会给自然环境中污染物分布造成一定的影响,所以,在采样地表水的时候,若是监测采样和河岸的距离比较近,那么可能会导致较大误差的出现,并且,随着季节的不断变化,河道涨潮的时间也是各不相同的,所以,在进行样本采集前,相关的工作人员必须全面的为实地调研工作的进行做好相关的准备,避免出现在错误的时间段进行样本采集的情况,最终会给监测结果造成较大的影响。 3)水样本保存的条件。为了降低环境条件以及微生物新陈代谢以及一些化学作用造成的影响,在保存样本的时候,一般会选择下面几种方式,分别是冷冻、冷藏以及进行保护剂的添加。地表水、污水样本本身的成分存在的差异较大,即便是保存条件是一样的,也很难保证同一类型样本中等待进行检测的物质的可行性都比较强。 三、大气采样 1.低浓度样品采集选择不同方式 就燃气电厂验收检测而言,所采集到的样本本身的氯化硫浓度比较的低,我们平时使用的地位电解法进行检测的时候,得到的结果无法将二氧化硫本身的准确浓度很好的监测出来,这种情况出现是因为化学法实际监测结果要比仪器法的出限低一些,这便需要监测的时候,相关人员选择化学法来采集样本和分析样本,确保最后得到的结果是准确的。 2,保存样品以及使用吸收液 使用吸收液收集到的相关样品,吸收液以及采集到的溶液本身的稳定性相对比较差,很容易被阳光照射、空气氧化以及现场环境温度变化等因素的影响而导致分解情况的出现,这便需要在低温的环境下进行样本的保存,特别是在夏天需要使用冰箱来进行冷藏,避免因为这些因素的影响,导致监测结果出现误差,在样本采集工作结束后,需要密封保存吸收管,并且需要尽快的分析样本。 3.检查采样的容器 若是样品本身的浓度比较高或者是选择的方法本身灵敏度比较强时,便可以直接通过采样法的手段来采集样品,最常用的容器包含了真空瓶、塑料气袋以及注射容器等。这些容器在使用前都必须做好气密性的监测,避免使用的时候出现漏气的情况,影响样品的收集。
基站故障处理流程规范
基站故障处理流程规范 IMB standardization office【IMB 5AB- IMBK 08- IMB 2C】
基站故障处理流程规范 1.概述 编制背景 为进一步规范移动基站处理流程,及时处理基站发生的故障,保证基站故障设备能够在最短时间得以恢复及对网络指标的影响降到最低,特制定基站故障抢修指导手册,以便基站维护人员发现、处理、分析故障问题提供参考。 编制单位 中国移动通信集团江西有限公司鹰潭分公司网络部 指标要求 按照基站维护服务技术规范书的要求,基站维护人员在接到设备障碍通知后,应及时到现场处理。 处理原则 1.维护人员应按“先室内,后室外,先软件,后硬件”的原则进行故障处理工作,即在排除 电力、光缆中断的因素后,再进入基站处理故障,在排除软件吊死、数据丢失等 软件原因后,再对调、更换硬件。 2.在充分了解故障信息的情况下,尽量缩短故障处理时长,更换需更换且仅需更换的 板件。因此,接到故障通知后,应根据通知内容对故障进行预判断,以便采取针 对性的处理措施,定位真正的故障点,避免错误信息误导,延长故障恢复时间。 3.维护人员在故障处理过程中,需协调其它部门或单位解决问题时,应立即展开协调 并向上级报告相关进展情况。
4.对载频,主控板,传输板等故障处理应禁止在网络指标考核(8:00-11:00,18:00- 20:00)时段进行处理 2.故障处理流程 3.基站故障分类及参考处理步骤 基站载频退服 步骤1:先要求机房查看载频信令是否激活,即是否处于WO状态。如果载频信令没办法激活或已激活,整个BCF也已重启,但载频依然退服,则带上对应型号的载频。 步骤2:到站后,若扇区没开跳频,则闭掉一块正常工作的载频,将故障板件和它对调。若扇区开了跳频,则先叫机房闭站。 步骤3:对调后,重新集成,观察载频是否能正常工作,如果故障随着载频走,则用新板更换故障载频;如果故障依然存在原位置,则可能与载频硬件无关,需重新定位故障点。 步骤4:故障恢复后,处理板卡标签和固定资产变动,签好出入登记本以及故障处理记录,离开基站。 基站因停电退服 步骤1:维护人员接到停电通知后,首先需询问当地电力公司,看该基站附近是否在做电力抢修,如果电力公司确定是在做电力抢修,详细了解将停电时长及恢复供电时间。 步骤2:在得到确切的时间后,根据基站固定资源调查表,或平时巡检表的信息,判断电池组的持续供电时间,如果电业局确定能恢复供电的时间很短,远小于电池组的安全供电时间,则不必带油机前往基站发电,但需每隔1小时跟踪一次供电恢复情况。如果电池组不能或勉强能撑到交流供电恢复时间,则需立即带上小油机去站上发电。
地理信息系统在环境管理中的应用
地理信息系统在环境管理中的应用 【摘要】本文简要介绍地理信息系统的概念和它的基本功能,列举地理信息系统在环境管理中的应用,对国内外环境地理信息系统的研究热点和方向进行阐述,并提出发展环境地理信息系统的策略和建议。 【关键词】GIS;环境地理信息系统;空间数据库 一、地理信息系统的概念 地理信息系统是收集、存储、管理、综合分析和处理空间信息和环境信息的计算机软硬件系统。它是GIS 技术在环境领域的延伸。 地理信息系统在环境管理中的应用的主要功能有: 1、基本功能包括对空间和属性数据的输入、存储、编辑,以及制图和空间分析等功能。编辑功能允许用户添加、修改、删除点、线、面或修改其属性信息;制图功能可以灵活多样地制作和显示及输出各种专题地图,如污染分布图、水功能区划图、环境规划图等等,地理要素可放大缩小以显示不同的细节内容,并能够测量地图上线段的长度或指定区域的面积。 2、空间统计分析是指对空间数据库中的专题数据进行
统计分析。包括各种属性数据的集中特征数、离散特征数及其分类分级统计等。 3、叠加分析功能允许两个或多个图层在空间上比较各空间要素和属性,分为合成叠加和统计叠加。合成叠加得到一个新图层,它将显示原图层的全部特征,交叉的特征区域仅显示共同特征;统计叠加可以统计一种空间要素在另一种空间要素中的分布特征。对不同的图层进行叠加分析,从而获得各种感兴趣信息。 4、缓冲区分析是GIS 的基本空间操作功能之一。例如,某地区有危险品仓库,要分析一旦仓库爆炸所涉及的范围,这就需要进行点缓冲区分析,结合与居民地图层的叠加分析,可以获取需要疏散的人口数等等。 综上所述,空间分析是地理信息系统软件的核心,空间统计分析、叠加分析、缓冲分析等功能为地理信息系统提供了强大的环境分析功能与广阔的应用空间。随着其功能的不断完善和发展,地理信息系统将为环境各部门提供一个功能强大的空间信息服务和管理工具,成为各部门日常工作不可或缺的工作手段。 二、地理信息系统在环境管理中的具体应用 由于地理信息系统具有强大的信息服务和管理功能,具
2G基站维护常用命令
NOKIA FLEXI EDGE 常用命令 1、查看目前ET 的使用情况ZDSB 查看在该ET 中建有几条信令(OMUSIG,TRXSIG)以及信令编号和分配的位置:(如果该 ET 以前已经在使用中) ZDSB:::PCM=(PCM 号),; 2、查看该ET 中已建信令的工作状态ZDTI ZDTI: 3、查看BCSU 工作状态ZUSI: 查看有多少个BCSU 在该BSC 中,有多少BCSU 在WO,哪一个BCSU 处于SP 状态 ZUSI: 4、查看该BSC 中每个BCSU 中容纳的TRX 数量ZEEI ZEEI:::; ZEEI::BCSU;查看各BCSU 分配的TRX / OMU SIG 个数。 5、查看该BSC 中BCF 和BTS 的编号ZEEI ZEEI:; 或ZEEP:可看到BCF / BTS /基站名 6、查看基站参数ZEQO 查看CI,NCC,BCC,MCC,MNC,LAC,HOP,MAL,MO,MS,HSN1,HSN2 等等 参数 ZEQO:BTS=号,ALL; ZEQO:LAC=号,CI=号,ALL;两命令看一个小区的所有小区参数集7、查看该BSC 的BSC 编号,BSCID 编号ZQNI ZQNI:; 8、查看该BSC 下所包含的软件包ZEWL ZEWL:可看到同类站型软件包个数 9、查看该BCF 软件包ZEWO ZEWO:看基站版本、软件、工作状态、属性(NW/BU/FB) NW: NEW BU: BACKUP FB: FALLBACK
10、添加或绑定软件包ZEWA 如BCF 软件包有更新的要更换 ZEWA: 11、添加或使用绑定的软件包ZEWV ZEWV:命令可改变基站属性 三、基站的启动 1、激活OMU 信令ZDTC ZDTC:BF034:WO; //BCF OMU 信令激活// ZDTC:T0341:WO; //LAPD 载波信令的激活// ZDTC:T0342:WO; ZDTC:T0345:WO; ZDTC:T0346:WO; ZDTC:T0349:WO; ZDTC:T034A:WO; DTC:修改D-CHANNEL 的状态,有四种状态:WO(工作)、BL (中断)、AL(允 许激活)、AD(拒绝激活)。 2、解锁TRX ZERS U:UNLOCK(解开);L:LOCK(闭) ZERS:BTS=034,TRX=1,:U; ZERS:BTS=034,TRX=2,:U; ZERS:BTS=035,TRX=5,:U; ZERS:BTS=035,TRX=6,:U; ZERS:BTS=036,TRX=9,:U; ZERS:BTS=036,TRX=10,:U; 3、解锁扇区ZEQS U:UNLOCK(解开);L:LOCK(闭) ZEQS:扇区号 4、解锁BTS ZEQS 参数说明:U 改为L 即可锁住基站,在ZEQS 中还可以加参数FHO 让用户在一定的时间内 切换出去再锁站,从而减少或避免用户掉话。 解锁顺序为TRX-BTS-BCF,锁站顺序则相反 ZEQS:BTS=034:U; ZEQS:BTS=035:U; ZEQS:BTS=036:U;