GPRS无线数据传输模块

远程监控GPRS（无线）模块使用安装说明
需要工具：
1、螺丝刀
2、电线
安装步骤：
一、接线
如图所示，有三个部件：电源、GPRS模块、控制器
1、将电源的正极（+）接GPRS模块的正极（+）；
2、将电源的负极（-）接GPRS模块的负极（-）；
3、将GPRS模块
RS485口的A接口连接控制器上面RS485口的A接口
4、将GPRS模块RS485口的B接口连接控制器上面RS485口的B接口
二、完成
完成接线后，接通电源绿灯长亮表示模块正常上线
注意事项：
1．目前通讯模块是移动模块，流量卡需要使用移动流量卡并保证正常通讯。

2．接线通电，通常1分钟以内通讯模块成功通讯，若通讯异常，可考虑连接天线，长时间通讯3/24/2014
不成功可以考虑通讯模块断电之后重新通电进行连接。

3．通讯模块电源应为12V电源适配器。

4.多个控制器使用一个通讯模块时，多个控制器RS485的A接口并联连接至通讯模块A接口，B接口并联连接至通讯模块B接口。

5.多个控制器时，网络地址位不能重复，如一个通讯模块连接5个控制器，控制器的地址位应
该1，2，3，4，5排列，不能重复，否则无法正常上线。

（地址位查询可以参阅控制器说
明书，以NA6942地址位设置是F88）。

6.如果由于模块安装在电控箱上不限于打开模块外壳可按如图所示将模块取下；。

gprs模块的工作原理GPRS（General Packet Radio Service）是一种移动通信技术，能够为移动设备提供快速的数据传输和连接服务。

GPRS模块是这种技术的重要组成部分，它允许设备通过无线网络实现网络连接。

本文将详细介绍GPRS模块的工作原理，包括GPRS技术的基础知识和模块的组成部分、电路原理以及通信协议等方面。

一、基础知识1、GPRS技术简介GPRS是基于GSM（Global System for Mobile Communications）网络的数据传输技术，它将移动通信与互联网相结合，提供了无线IP数据传输服务。

与GSM相比，GPRS的优点包括更高的速度、更低的延迟、更灵活的数据传输和更低的成本等方面。

GPRS技术的核心在于将数据分为数据包进行传输，而不是像传统的通信技术一样将数据以电路交换的方式进行传输。

2、GPRS的工作原理GPRS系统主要由三部分组成：无线终端设备（Mobile Station，MS）、GPRS支持节点（GPRS Support Node，GSN）和GPRS核心网络（GPRS Core Network）。

无线终端设备包括移动电话、笔记本电脑和其他移动设备，用于与GPRS网络进行通信；GPRS支持节点包括SGSN（Serving GPRS Support Node）和GGSN（Gateway GPRS Support Node），用于管理无线终端设备和处理GPRS数据传输；GPRS核心网络包括多个SGSN和GGSN，用于提供网络连接和数据传输服务。

GPRS数据传输主要分为两个阶段：数据包发送和数据包接收。

在数据包发送阶段，无线终端设备发送数据包到GPRS支持节点，GPRS支持节点将数据包传递给GPRS核心网络，最终到达目标设备；在数据包接收阶段，目标设备从核心网络中接收数据包，并将其传递给GPRS支持节点，最终到达无线终端设备。

GPRS支持节点通过GPRS链路控制协议（GPRS Tunneling Protocol，GTP）传输数据包，确保数据包的可靠性和安全性。

GPRS猫、GSM Modem、GPRS模块选型指南市场上GPRS模块的种类多种多样，令人眼花缭乱，但总的来说典型的GPRS模块就分为三类，接下来就和小亿一起看看GPRS模块的种类以及怎么选型吧！一、GPRS DTU(通常称为GPRS数字传输单元、GPRS透过模块)GPRS DTU内部封装了完整的TCP/IP等协议栈，为无线传输提供了透明的TCP/IP通道。

在软件设计中，封装协议栈的内容，具有嵌入式OS，在硬件上看作嵌入式PC和无线接入部分的结合，在窗口中进行数据通信。

主要应用于工业领域，但GPRS modem通常需要使用PC软件进行预数据处理，以实现类似的功能。

在这种格式的应用程序中，PC通常必须连接到GPRS Modem才能连接到外部数据网。

GPRS DTU的四个核心功能：●内部综合TCP/IP协议栈●提供串行数据的双向转换功能●支持自动心跳，使终端设备持续在线(DTU包括开机自动拨号，使用心跳分组持续在线)-如果长时间没有数据通信，移动网关将DTU和中心连接●对应参数配置，永久保存。

在FLASH或EEPROM中保存数据中心的IP地址、端口号、串行端口的波特率等。

电源接通后，根据设定的参数自动动作。

更高级的GPRS DTU还支持数据中心域名解析、支持远程参数设置/远程固件升级、支持远程消息/电话唤醒、本地串行固件升级的。

二、GPRS/GSM Modem(纯GPRS/GSM调制解调器，经常被称为GPRS猫)。

●GPRS调制解调器是接入GPRS分组网的物理信道，本身没有OS，必须依赖于计算机(功能上类似于有线调制解调器)，不能在计算机OS上进行PPP拨号连接，通常是PC在操作方式中，GPRS DTU和GPRS Modem最大的区别在于GPRS DTU内部CPU主动控制拨号，处理TCP/IP协议分组，而GPRS Modem是被动的，拨号和TCP/。

三、带TCP/IP协议栈的GPRSmodem●GPRS/GSMmodem和TCP/IP协议栈一起封装，内部有CPU、FLASH、RAM、控制单元等硬件，与DTU功能类似。

基于APN/VPDN专网业务实现GPRS DTU无线数据传输方案1、前言利用GPRS无线传输技术，基于GPRS 网络，通过APN/VPDN专网业务，利用才茂通信DTU 无线传输终端设备，可以为电力、水利、热网、环保、交通等行业提供实时的数据传输、采集、发布、远程管理与控制、实现远程无线数据传输的完美解决方案。

2、关于GPRS、APN与VPDN2.1、GPRS（General Packet Radio Service）通用无线分组业务所谓GPRS，是一种基于GSM系统的无线分组交换技术，提供端到端的、广域的无线IP 连接。

GPRS充分利用共享无线信道，采用IP Over PPP实现数据终端的高速、远程接入。

作为现有GSM网络向第三代移动通信演变的过渡技术（2.5G），GPRS在许多方面都具有显著的优势。

GPRS有下列特点及优点：1）、可充分利用现有资源------中国移动全国范围的GSM电信网络，灵活、方便、快速、低建设成本地为用户数据终端提供远程接入网络的部署；2）、传输速率高，GPRS数据传输速度可达到57.6Kbps，最高可达到115Kbps—170Kbps，完全可以满足用户应用的需求，下一代GPRS业务的速度可以达到384Kbit/s；3）、接入时间短，GPRS接入等待时间短，可快速建立连接，平均为两秒；4）、提供实时在线功能“alwaysonline”，用户将始终处于连线和在线状态，这将使访问服务变得非常简单、快速；5）、资费便宜，计费合理：GPRS是按流量计费的，GPRS用户只有在发送或接收数据期间才占用资源，用户可以一直在线，按照用户接收和发送数据包的数量来收取费用，没有数据流量的传递时，用户即使挂在网上也是不收费的。

GPRS业务，具有接入迅速、永远在线、流量计费等特点，在远程突发性数据实时传输中有不可比拟的优势，特别适合于频发小数据量的实时传输,因而GPRS业务在某些行业上有特殊的应用。

GPRS模块使用说明
一、简介
二、特点
1、GPRS模块具有低功耗，可以在低功耗的电力环境下实现数据传输，可以大大节省电力；
2、GPRS模块具有较高的穿墙率和覆盖范围，可以实现建筑物内外的
覆盖，特别是在城市区域内；
3、GPRS模块可以支持多种无线通信技术，如GPRS，EDGE，HSDPA等，可以实现高效的数据传输；
4、GPRS模块的应用程序广泛，包括远程监控、无线广播、车载移动
通信等等；
5、GPRS模块具有安全特性，可以通过加密技术来保护数据的安全性。

三、应用
1、GPRS模块可以用于远程监控，可以实时监测物理设备的状态，如
温湿度、功率、电压等；
2、GPRS模块可以用于无线广播，可以实现远距离的无线数据广播，
如新闻、广告等；
3、GPRS模块可以用于车载移动通信，可以实现车载的无线数据传输，如位置监测、车辆信息交互等；。

gprs数据传输模块（GPRS DTU）安装接线的注意事项1.安装场地选择：电源：现场可提供10-30V/DC电源，或交流220V电源经电源模块转为10-30V/DC电源，或使用太阳能供电的环境。

环境：温度范围为-20℃－+70℃，湿度范围为RH5%－95%（无凝露），无腐蚀性气体、无液体喷溅、无金属粉尘、无强烈震动、无强磁干扰。

网络：中国移动公司GSM/GPRS信号能覆盖到的地方。

2.安装接线注意：①通电前，天线一定要在安装状态，以免射频部分阻抗失配，损坏GPRS无线数据传输模块。

注：天线在GPRS无线数据传输模块中起接收和发射通信信号的作用。

②天线不要放在密闭的金属箱内，或容易被人发现并摘取的地方。

gprs数据传输模块（GPRS DTU）具体信息DATA-6123/DATA-61241.产品概述gprs数据传输模块（GPRS DTU）采用低功耗设计，通过GPRS/CDMA或短消息方式远程传输数据，特别适用于太阳能供电的监测场合，可大大减少太阳能供电成本并降低施工难度，广泛应用于气象、水文水利、地质等行业。

2.产品功能◆通信功能：支持GPRS/CDMA和短消息双通道传输数据；支持与多中心进行数据通信。

◆采集功能：采集串口设备数据，如串口仪表、采集器、PLC等。

◆远程管理功能：支持远程参数设置、程序升级。

3.产品特点◆低功耗设计，实时在线平均电流≤10mA/12V。

◆DATA-6123体积小巧、安装方便。

◆弹出式卡槽设计，安装SIM卡无需打开设备外壳。

◆支持短消息、专线、VPN专网等多种组网方式；支持域名解析功能。

◆支持UDP、TCP 协议；支持数据透明传输。

◆支持各家组态软件和用户自行开发软件系统。

◆工业级设计，适用室外恶劣环境。

◆采用上位机召测的数据上报方式；可扩展支持定时上报、数据变化上报等上报方式（扩展功能需定制）。

4.技术参数串口配置：1路RS485，2路RS232。

数据格式：8 位数据位，1 位停止位，校验位（奇、偶、无）可设定。

GPRS模块技术规范1. 介绍本文档旨在规范GPRS（General Packet Radio Service）模块的技术要求和规格。

GPRS是一种移动通信协议，可用于在无线网络上进行数据传输。

本文档将详细描述GPRS模块的功能、性能和接口规范。

2. 模块功能GPRS模块提供以下功能：- 数据传输：支持通过GPRS协议在无线网络上进行数据传输，包括发送和接收数据包。

- 网络连接：支持与远程服务器建立稳定的网络连接，以便进行数据通信。

- 电源管理：提供低功耗模式和电源管理功能，以优化模块的电池寿命。

- 接口：提供与主控设备的通信接口，包括串口、SPI等。

- 信号强度检测：支持检测当前所处位置的无线信号强度。

3. 技术规格以下是GPRS模块的一些主要技术规格：- 通信频率：支持多个频段的通信，以适应不同的无线网络环境。

- 数据接口：支持串口和SPI接口，以与主控设备进行数据交互。

- 电源要求：工作电压范围、电流消耗等相关电源参数要求。

- 尺寸和接口类型：模块的尺寸要求和物理接口类型，如SIM 卡槽或天线接口等。

- 安全性：支持数据加密和身份验证等安全机制，以确保数据传输的安全性。

4. 兼容性GPRS模块应具备与其他相关设备和协议的兼容性，以便与现有的通信系统集成。

模块应支持标准的AT命令集，并能够与不同品牌和型号的主控设备进行良好的兼容性。

5. 测试和认证GPRS模块应符合国际或地区相关的通信技术标准，需要进行各项测试和认证以确保其符合规范要求。

相关测试和认证标准包括但不限于电磁兼容性测试、射频性能测试和安全性认证等。

6. 文档要求为了方便用户使用和集成GPRS模块，应提供详细的技术文档和用户手册。

文档应包含以下内容：- GPRS模块的功能说明和使用方法。

- 接口的物理和电气规格。

- AT命令集和通信协议规范。

- 故障排除和故障处理指南。

- 安装和维护要求。

7. 维护和支持GPRS模块供应商应提供及时的技术支持和维护服务，以及软件更新和修复。

什么是DTU模块？什么是GPRS模块？DTU模块与GPRS模块的区别？什么是DTU模块？DTU(DataTransferUnit，数据传输单元)是一种用于将串口数据转换为IP数据或将IP数据转换为串口数据并通过无线通信网络进行传输的无线终端设备。

DTU模块扮演的角色则负责在通信过程中，将传输数据的链路两端发送数据信息的模块单元。

经过DTU模块的处理，它们传输的信息被格式转换和数据校对。

而CPU控制模块、无线通信模块和电源模块共同构成了DTU模块的硬件部分。

什么是GPRS模块？如上所述，DTU模块的硬件组件主要包括CPU控制模块、无线通信模块和电源模块。

无线通信模块可以是GPRS模块、3G模块、4G/LTE模块等，因此DTU 可以分为GPRSDTU、3GDTU、4GDTU等。

DTU模块与GPRS模块的区别？从DTU和GPRS的定义可以看出，GPRS模块只是DTU中使用的无线通信模块。

DTU是一种带有GPRS模块或CMDA模块的设备，同时可以通过串口或网口传输数据。

简单理解：DTU是一种透明的传输设备，可以承载GPRS或其他4G网络DU，它是使用GPRS和其他网络制作的。

GPRS模块是单个通信模块，DTU是一台整机。

虽然它们都是用来一起传输数据的，但DTU只能发送有用的数据，不需要控制AT 命令，这些都是由DTU处理的。

GPRS模块要求用户在发送数据之前非常熟悉AT命令。

从这一方面来说，DTU使用起来更加方便简单，更加稳定，使用后即可使用。

GPRS模块需要一段时间才能启动，但也要确保它始终在线，这相当令人头疼。

而在价格方面，DTU模块的价格更是让人尴尬。

如何选择DTU模块和GPRS模块？首先要知道，GPRS模块还分为GPRSDTU模块和GPRSRTU模块。

它们之间的区别在于，GPRSDTU模块只能用于传输RS232和RS485等串行数据；而GPRSRTU 模块只能用于传输串行数据。

除上述功能外，还可以采集模拟、脉冲、开关等各种仪表输出的数据信号。

gprs模块工作原理
GPRS（General Packet Radio Service）模块是一种用于移动通信的技术，它通过无线网络传输数据。

下面是GPRS模块的工作原理：
1. 连接建立：GPRS模块首先与移动通信网络进行连接。

它通过与移动通信基站进行通信，完成身份验证和注册过程，确保模块与网络的有效连接。

2. 数据封装：GPRS模块将要传输的数据进行封装。

数据被分割成小的数据包，并添加必要的头部和尾部信息，以便在网络中进行传输。

3. 数据传输：封装后的数据通过GPRS模块与网络之间的无线连接进行传输。

GPRS模块利用无线信号将数据包发送到网络中。

4. 路由选择：在网络中，数据包将通过一系列的路由器进行传输，以找到目标地址。

这些路由器根据接收到的数据包的目标地址将其转发到正确的目的地。

5. 数据接收：目标设备收到数据包后，GPRS模块将数据进行解封，提取出有效的数据，并将其传递给目标设备。

6. 数据传输确认：一旦目标设备收到数据并进行处理，它会向GPRS模块发送确认消息，以确保数据发送成功。

7. 连接断开：在数据传输完成后，GPRS模块与移动通信网络之间的连接会被断开，释放网络资源。

总的来说，GPRS模块通过与移动通信网络进行连接，并利用无线信号将数据进行封装和传输，以实现移动通信网络中的数据传输功能。

GPRS无线收发模块的安装及检测唐山平升电子技术开发有限公司地址：河北省唐山市国家高新技术开发区创业中心C座二层售前咨询：400-611-8633 售后服务：400-691-8633 公司网址： 产品的安装1.1概述安装使用GPRS 无线收发模块前需要仔细阅读本文档，如遇到不理解的内容时，需要与平升公司客户服务中心取得联系，在专业工程师指导下安装使用该模块。

客户服务中心电话： 400-691-8633 (免长途费)。

1.2安装所需工具小一字螺丝刀 一个 小十字螺丝刀 一个1.3 DATA-6106 GPRS 无线收发模块安装1）、安装SIM 卡及天线注意：请勿带电安装SIM 卡。

安装步骤：（1）拆下绿色的接线端子；（2）拧下模块壳体上盖的两个螺丝，谨慎打开模块的上盖，可见到SIM 卡座；（3）顺着卡座上标注的OPEN 旁边箭头方向水平推动卡座上盖，卡座上盖弹起； （4）把SIM 卡插入卡座上盖后放平压紧，按箭头反向推动，锁住卡座上盖。

（5）安装完毕后，盖好模块上盖、扣紧，拧上螺丝，插上接线端子。

（6）把天线接头与模块顶部天线接头对准拧紧。

注意：（1）如果GPRS 无线收发模块安装在密闭的金属箱体内，无法接收GPRS 信号，建议使用吸盘式天线，天线的信号接收端放到金属箱体外面。

（2）安装SIM 卡时，请勿损毁SIM 卡座上的金属连接引脚、卡座上盖与底座连接部位。

座上盖2）、导轨安装每个GPRS 无线收发模块自带一个DIN 导轨卡具，模块和卡具之间使用长螺栓连接即可，安装导轨卡具后，模块可以方便地安装到DIN 导轨上。

3）、供电电源安装电源线：电源线根据接线端子的要求接到端子右侧两个接线柱上，不要把正极和地线接错。

模块需要供电电压： +10～30V DC 。

模块功耗：最大电力消耗10W ；待机电力消耗1W 。

4）、检测网络情况将一张移动公司开通GPRS 业务的SIM 卡安装到GPRS 模块内，安装好天线后加电，NET 灯亮起说明模块已经登陆GPRS 网络，网络可以使用。

gprs模块工作原理GPRS模块是一种用于移动通信的无线模块，它可以实现数据的传输和通信功能。

GPRS模块的工作原理是通过无线电波进行数据传输，它可以在全球范围内进行通信，是一种非常方便和实用的通信方式。

接下来，我们将详细介绍GPRS模块的工作原理。

首先，GPRS模块通过SIM卡与移动通信运营商的基站进行连接。

当用户发送数据时，GPRS模块会将数据通过SIM卡发送到基站，然后基站将数据转发到目标设备。

这个过程类似于我们使用手机进行通话或发送短信的过程，只不过GPRS模块是专门用于数据传输的。

其次，GPRS模块使用的是TDMA（时分多址）技术和8PSK调制技术。

TDMA技术可以将时间分成很多个时隙，不同的用户可以在不同的时隙中进行通信，这样就可以实现多用户同时通信的功能。

而8PSK调制技术可以提高数据传输的速率，使得数据传输更加高效和稳定。

另外，GPRS模块还采用了分组交换的方式进行数据传输。

在传统的电路交换方式中，一条通信线路在通信过程中会一直被占用，无法充分利用资源。

而分组交换方式可以将数据分成小的数据包进行传输，不同的数据包可以通过不同的路径到达目的地，这样可以充分利用网络资源，提高数据传输的效率。

此外，GPRS模块还具有自动重传机制和差错校正功能。

在数据传输过程中，由于信道的不稳定性或者干扰等原因，可能会导致数据传输出现错误。

GPRS模块可以通过自动重传机制进行数据重发，保证数据传输的可靠性。

同时，GPRS模块还可以通过差错校正功能对接收到的数据进行校正，确保数据的准确性。

总的来说，GPRS模块的工作原理是通过SIM卡与基站进行连接，利用TDMA 技术和8PSK调制技术进行数据传输，采用分组交换方式进行数据传输，同时具有自动重传机制和差错校正功能。

这些技术和功能使得GPRS模块成为一种高效、稳定和可靠的数据传输方式，广泛应用于物联网、智能设备等领域。

希望通过本文的介绍，您对GPRS模块的工作原理有了更加深入的了解，如果您有更多的疑问或者需要进一步了解GPRS模块的相关知识，可以随时联系我们，我们将竭诚为您服务。

什么是GPRS模块？什么是GSM模块？GPRS模块与GSM模块的区别对别？GPRS和GSM模块都是无线传输模块，许多人将二者混淆。

今天小亿带大家来看一看这两种模块之间区别。

GSM模块是什么？GSM模块是将GSM射频芯片，基带处理芯片，存储器，放大器设备等集成在基板上的功能模块，以提供独立的OS，GSM射频处理，基带处理和标准接口。

GPRS模块是什么？简单来讲，GPRS无线模块就是将串口通讯转为GPRS无线通讯的设备。

利用du运营商网络为用户提供无线长距离数据传输功能，提供TTL串口接口。

GPRS模块可以是在设备无网络或WIFI的野外环境下，与服务器进行数据交互。

GPRS模块和GSM模块之间的区别1.传输方式传输模式分为主动模式和被动模式，但传输频带不同。

可以看出，GSM模块的传输相当于2G频段，GPRS模块的传输频率相当于2.5G，GPRS模块的传输速度更快。

2.网络信号根据Internet需求，GSM网络信号需求较低，而GPRS网络信号需求较高，因此发送类似于蜂窝电话网络信号的消息没有问题，但是呼叫被阻止。

3.校正计算方法GPRS模块的流量校正方法通常使用字节来校正流量。

其中以4G路由器和4G模块（例如GPRS模块）为下一个RTU。

中心站发送一个8字节的收集命令。

我们返回的数据是20个字。

6S周期，并且GPRS模块增加了约170个网络协议字节，分别为1小时，118,800字节，24小时，285,1200字节和1个月8,5536,000字节，即80M流量数据包。

在实际使用中，模块和心跳数据包也会消耗一定数量的数据，因此通信数据包需要稍微放大。

4.访问速度与GSM的9.6kbps接入速度相比，4G路由器和4G模块GPRS的接入速度为171.2kbps，比许多人快十倍以上。

GPRS不仅具有快速的访问速度，而且建立连接请求的时间也非常短。

GSM需要10到30秒。

5.传输距离就传输距离而言，GPRS模块和GSM模块并排在同一水平线上。

我在这里把常见的GPRS模块分成3种：（1）GPRS DTU（GPRS数传单元，常称GPRS透传模块）（2）GPRS/GSM modem （这是一种纯的GPRS/GSM调制解调器，常称为GPRS猫）(3) 包含tcp/ip协议栈的GPRS modem （其将GPRS/GSM modem 和tcpip协议栈封装在一起，内部有cpu，flash，ram，控制单元等硬件，和dtu功能类似）GPRS DTU的理解及应用GPRS DTU 内部封装了完善的TCP/IP等协议栈，可为无线传输传输提供透明的TCP/IP通道。

主要应用于工业领域，而GPRS modem通常要完成类似的功能必须借助于PC机的软件和硬件资源，如CPU、Memory和TCP/IP协议栈等，所以我们经常可以看到PC接一个无线的Modem来连接到外部的数据网。

采用了GPRS的微控制器系统可以实现无线数传输领域的复杂应用，在远程抄表、工业控制、遥感\测、智能交通领域都得到了广泛的应用，下面是一个典型的应用：在使用了RFID技术的公交领域，非接触卡得到了普便的应用，乘客的刷卡交易数据通常都存储在车载的读卡机具中，如果采用特定设备依次对每辆车的数据提取是一个非常繁杂的工作，而采用无线传输方式的优势显然是不言而喻的，通过车载无线设备，可以以灵活的方式将乘客的交易数据传输到数据中心进行统一处理，此外还可以实现远程的公交调度控制以及公交车电子站牌GPRS信息发布的发布等等。

当然，采用GPRS进行无线传输仍然存在一些问题需要更好地解决，比如传输的可靠性问题、传输速率等，目前GPRS的理论带宽是171.2Kbps，实际应用带宽在40Kbps左右。

GPRS无线设备连接到外部数据网两种方法的比较！我们使用GPRS无线设备做数传的时候，在连接到外部数据网时通常有两种方法：( I ).拨号上网：常见的如拨ATD *99***#( II ).指定Server的IP地址、Port端口号，使用特定的AT指令来连接到外部的数据网，也即internet例如：Simcom的GPRS模块SIM300C采用的指令为：AT+CIPSTART = "TCP","211.247.26.252","3030",即可连接具有公网IP地址为211.247.26.252，TCP端口号为3030的Server。

外文文献：A Detailed Implementation and Analysis of Data Center of GPRS DTUZhen Yu Dept. of Automation Xiamen UniversityXiamen, China****************.cnZhong Zheng Dept.of AutomationXiamen UniversityXiamen, China*********************Abstract—This paper gives an overview of the architecture of the telecontrol system based on GPRS. The objectives of this paper are two fold. One is to present the design and implement of the data center of GPRS DTU. The other is to investigate its performance. According to the features of GPRS DTU, data center provides reliable communication between members of a group by implementing the telecontrol system in the client/server model. With the use of the data center, it is of practical significance to implement multiple master stations to receive data from all slave stations simultaneously and to control all slave stations in parallel. The data center design parameters include real- time control, deployment simplification and the ability to provide high availability, scalability and reliability.Keywords-GPRS DTU; data center; telecontrol system; master station; slave stationI.I NTRODUCTIONIn recent years, it is a major trend to use wireless networks in the large-scale industrial production systems to control and manage the components which scattered in the different remote areas. In order to ensure the appropriate operation of the system, these components must be operated under the unified command to coordinate the work among them through the scheduling agencies.The scheduling agencies should keep abreast of the actual production situations of the various parts. On this basis it can make regulation and control strategies on time. With the rapid development of network technology, the telecontrol technology which is the combination of scheduling management and modern control technology can not only meet the real-time dispatch, but also ensure high reliability. For implementing efficient measuring and monitoring processes, it’s facility for the telecontrol system to transmit the information through the use of wireless networks. One prominent communication technology for this service is the GPRS. Thus, under the premise of lowering the cost and enhancing the competitiveness, more and more enterprises are applying the GPRS technology to replace the traditional long distance leased line. In this paper, we give a detailed implementation of public network access solution and analyze its performance.II.C HARACTERISTIC OF GPRS NETWORK The most widely deployed public mobile data network, which enables the integration of IP with mobile networks and constitutes a migration step toward third-generation communication systems, is the General Packet Radio Service (GPRS) [1]. GPRS attempts to reuse the existing Global System for Mobile Communication (GSM)network elements as much as possible, but in order to effectively build a packet-based mobile cellular network,some new network elements, interfaces, and protocols are required [1]. The new network nodes are called GPRS support nodes (GSNs). The SGSN is responsible for the delivery of data packets from and to the mobile station(MS) within its service area [2]. The GGSN acts as an interface between the GPRS backbone network and the external packet data network [2]. GPRS supports applications based on standard protocols for packet-switch data communication. The standards include interworking procedures with IP and X.25 networks [3]. This makes the realization of the GPRS services feasible, when GPRS exchanges information with the external networks which based on the IP protocol suite, such as Internet.The traffic characteristic of the packet-mode data effectively supported by GPRS ranges from intermittent, bursty data transfer, to frequent transmission of “sma ll”amount of data, to occasional transmission of “large”amount of data [3]. An important benefit of GPRS is that the radio channels in GPRS are shared between multiple Mobile Stations (MS). Second, multiplexing on the air interface permits efficient support of bursty traffic [3]. GPRS transmission rate can be raised to 56 or even 114 Kbps. Moreover, connections and transmission will be more convenient and easier, for they no longer need the intermediary converters among the existing wireless applications [3]. More importantly, once activate the GPRS applications, it will always remain online. However,mobile subscribers only pay according to the amount of information transferred, not in terms of the occupied time.III.D EMAND ANALYSIS FOR THE TELECONTROLSYSTEMThe telecontrol system is a broad term which refers to the system of monitoring and controlling the production process. The equipments which constitute the telecontrol system include the factory station, the scheduling station and the telecontrol channel. Traditionally and customarily, we call the factory station and the scheduling station as the slave station and the master station respectively.In the sequel, the proposed telecontrol system based on GPRS deployment scenario is presented and analyzed. The system requires to provide with the conveniences for easy installation, easy usage, remote manageable, easilyexpand, and only takes up little bandwidth for transmitting monitorFigure 1. The architecture of the telecontrol systemand management information, etc. As shown in Fig. 1, some of the key components of the architecture are as following:GPRS DTU is the abbreviation for GPRS Data Terminal Unit. In simple terms, DTU is the GPRS wireless device which specially applied to transmit the serial data through the GPRS networks. DTU provides serial communication interface, such as RS-232 or RS-485. Every station connects with the GPRS DTU through RS- 232. In practice, each GPRS DTU needs a build-in SIM card which was used to apply for GPRS services.The master station is the monitor and management center, which provides a convenient and integrated user interface; with easy installation and usage, as well as allowing for telecontrol and teleadjusting. Relatively, the slave station is the remote terminal unit, which is responsible for data acquisition and transmission.The data center implements the communication among numbers of DTUs though the use of Client/Server model. The data center acts as a server, maintaining and managing bidirectional communication between the master stations and slave stations though DTUs. In such a communication model, where all stations are connecting to the data center, and data transfer is carried out using mobile devices (such as GPRS DTU), stability and real-time are considered paramount.IV.F UNDAMENTALS OF GPRS DTUA.Working ProcessOnce the GPRS DTU powers on, it firstly reads out the internal flash saved operating parameters which include GPRS dial-up parameters, serial port baud rate, the data center IP address and port number, and so on. After the success of a dial-up, a internal IP address will be randomly allocated to GPRS DTU. In other words, GPRS works in a mobile network, but its network IP addresses are not usually fixed but changed along with each dial-up.It means that GPRS DTU is a mobile device within the internal LAN (Local Area Network) and communicates with the external public Internet network through the mobile gateway (GGSN). So it is impossible to communicate between the master station and the slave station directly. But DTU can connect to the data center with a fixed public network IP address or domain name automatically and keep this communication link on line. Therefore, GPRS DTU needs to take the initiative to connect to the data center.Specifically, GPRS DTU initiates a TCP (Transmission Control Protocol) or UDP (User Datagram Protocol) communication request to the data center though the data center IP address and port number which were configured in advance. After receiving the response from the data center, GPRS DTU makes a successful handshake with the data center and maintains the communication link. If the communication link was interrupted, GPRS DTU would immediately re-handshake with the data center.Then the TCP/UDP bidirectional communication links between GPRS DTU and the data center have been set up.GPRS DTU have integrated TCP/IP protocol stack, so it’s relatively simple to complete the conversion between user serial data and GPRS network packet. While receiving the user’s serial data, GPRS DTU immediately encapsulates the serial data into a TCP/UDP packet and sends it to the data center. Conversely, when GPRS DTU receives the TCP/UDP packet from the data center, it will extract useful data from the packet, and send the data to the user equipment through the serial port at once.More importantly, one of the advantages of GPRS networks is that it supports GPRS terminal equipments to keep online permanently, so typically GPRS DTU is designed to support this function. It requires that the features of GPRS DTU include automatically dial-up, maintaining a permanent online, supporting re-connection automatically, and so on.B.Heartbeat PacketWhen there is no data transmission for a certain time, the mobile gateway will disconnect the communication link between the data center and GPRS DTU automatically. For maintaining the connection online,DTU heartbeat packet would be send before this link is disconnected. The problem is how long did DTU heart packet be send. If the send-time interval was set too long,there is no data transmission. Then the mobile gateway interrupts the link. On the contrary, the data center ca n’t receive the heartbeat packet on time because of the wireless network delay. On the earth, GPRS DTU will determine that the communication link has disconnected and re-connect automatically. No matter what kind of situations, it will increase instability to the telecontrol system.Fig. 2 shows the experimental results for setting the send-time interval of the heartbeat packet analysis. One observation is that GPRS DTU always re-connects to the data center per 160 seconds more or less, when the send-time interval of the heartbeat packet was set as 60 seconds in Xiamen, China. So we reset the time parameter as 160seconds, it greatly improve the reliability and stability of the system.Figure 2. The reconnected time intervalFigure 3. The frame format of DTU register packetC.Register PacketOnce the TCP communication link between GPRS DTU and the data center was set up successfully, the DTU sends the register packet to the data center at first. As shown in Fig. 3, the content of the register packet includes identification (ID) number to identify GPRS DTU, SIM card number for opening GPRS services, and dynamic IP address being allocated. After the data center receives the register packet, it will get hold of the basic information of GPRS DTU. Since the ID number is unique and fixed, it can be used as the station address to identify DTUs or stations naturally. By extracting the ID number from the register packet, it’s easy to establish and maintain a DTU list to record the connection status of the all stations.The aforementioned discussions are both necessary and sufficient for designing and implementing the telecontrol system. It is the data center that the normal communication between the master station and slave station depends entirely on through the use of GPRS DTU.V.DESIGN AND IMPLEMENT OF DATA CENTERA.Design ScenarioThe work in this paper primarily implements the functions of communication for the data center of GPRS DTU on the platform of VC++6.0 SP4 and Windows XP, which was built to evaluate the performance of remote access GPRS-Internet networks. For reaching a desired quality of service and maintaining the system in a reliable and stable operation, design and implement of the data center is very important. Furthermore, the aforementioned telecontrol system network topology is a star network. In a star network, the failure of a single link can not affect the performance of the whole system. However, if the data center fails, each station in the system will become disconnected. As shown in the Fig. 4, combining with the knowledge of network programming, the data center refers to as a socket interface which is a virtual interface that can be established between the transport layer and application layer of the TCP/IP Suite of protocol. From the perspective of reliability, the socket program should choose the SOCK_STREAM which based on reliable connection TCP (Transmission Control Protocol).The data center is fairly meaningless if it cannot service multiple clients at the same time, usually asynchronous I/O calls and multithreading is used for this purpose. By definition, an asynchronous I/O call returns immediately, leaving the I/O call pending. Nowadays, It is commonly known that asynchronous Input/Output Completion Ports (IOCP) is one of the most efficient ways. By using IOCP, we can overcome the “one-thread-per-client”problem. Threads are system resources that are neither unlimited nor cheap. IOCP provides a way to have a few I/O workers thread handle multiple client s’input/output “f airly”. The threads are suspended, and do n’t use the CPU cycles until there is something to do.When using asynchronous I/O calls, we have to provide a private buffer to be used with the I/O operation.There are some considerations that are to be taken into account when we allocate buffers to use. From the storage structure point of view, to allocate and free memory is expensive, therefore we should reuse buffers which have been allocated. We save buffers in the linked list structures. A list container represents noncontiguous memory. It is efficient to insert or erase an element at any point.Inserting or removing an element in a list container does not move any other elements. It significantly improved the efficiency of the data center.Figure 4. Flows of the data center softwareFigure 5. The frame format of the telecontrol informationmunication ProtocolIn the telecontrol system, in order to send and receive information correctly, there must a set of rules on the information transmission sequence, information format, information content and so on. Usually we call this set of rules as communication protocol. As shown in the Fig. 5, the telecontrol information of each frame begins with the synchronization word, as well as the control and information words. The most important thing is that the control word contains the ID numbers of the source station and destination station. The data center can properly forward the frame though the ID numbers of the destination station.C.Measurement ProceduresThe telecontrol system deploys two master stations and eight slave stations. We measure some metric performance in TCP mode. These metrics are used in our experiments as they have a direct impact on the ultimate performance. During our experiments, the following parameters were used to quantify the services provided.Overall transfer time: is the amount of time it takes one packet to travel from one station to another; the parameter is measured in seconds.Overall response time: consists of subtracting the time at which the telecontrol segment is sent from the time at which the acknowledgement arrives; the parameter is measured in seconds.D.Design issuesIn the telecontrol system, given a real-time control has been a key challenge to many designers. Real-time is an important design parameter in the whole system. There are two main factors that have a great impact on the real-time control.One is bandwidth of the communication channel. In GPRS, DTU can access the public data networks directly and easily using their standard protocol address. A GPRS MS (mobile station) can use between one and eight channels over the air interface. GPRS system has a very short access time to the network. The theoretical maximum throughput of the GPRS system is 160 kbps per MS when using all eight time slots without any error correction [4]. To fully exploit the high capacity of GPRS, the slave stations can periodically take the initiative to send the telecontrol messages to the master stations in accordance with a given order. And the master station transmit “larg e”amount of telecontrol information to all slave stations occasionally.Another key element is the forwarding rate of the data center. Deciding on the process structure of the data center is a major problem in the design of any service. The data center is required to operate efficiently in peek periods, when dozens of active stations need to be simultaneously. One of the best solutions for the data center architecture is the use of IOCP which has been discussed above. The real-time of the telecontrol system can be illustrated by overall transfer time and overall response time. As shown in the Fig. 6, overall transfer time is less than 5 seconds. And overall response time is approximately no more than 10 seconds. It basically reaches the ministerial standard real-time control.Another design issue involves fault tolerance. Communication faults, malicious attack, access violation should all be tolerated to some extent. A fault-tolerant system should continue to function, perhaps in a degraded form, when faced with these failures. In a typical connection, The GPRS DTU sends a message asking the data center to accept it, once it connected to the datacenter. The data center returns the accept approval to the GPRS DTU. The GPRS DTU acknowledges this approval and then is allowed onto the data center. A “denial-of-servi ce” attack is characterized by an explicit attempt by attackers to prevent legitimate users of a service from using that service or accessing information. Usually one GPRS DTU connects to the data center for a long time, but it does n’t send a message asking the data center to accept it. Consequently prevent other GPRS DTUs from connecting to the data center on time, even disable the data center. One of the more common methods of blocking this attack is to set up a timer. The time of GPRS DTU connecting to the data center ca n’t exceed a given time(such as 60 seconds), or else the data center will close this vicious connection compulsorily.Still another issue is scalability –the capability of a system to adapt to increased service load. Systems have bounded resources and can become completely saturated under increased load. Even worse, expanding the system can call for expensive design modifications. A scalable system should have the potential to grow without these problems. In the telecontrol system, the ability to scale up gracefully is of special importance, since expanding the system by adding one or more new stations is commonplace. At first, No matter how many the number of slave station or master station increases, we can solve scalability and availability though the use of the forwarding function of the data center. The data center can forward the telecontrol information which received from the master station to all the slave stations, and vice versa. Secondly, with introducing the thread pooling and IOCP into Windows XP, Server applications make extensive use of thread pooling techniques to delegate client requests to worker threads, which is implemented as a thread pool so that they can achieve better throughput. After serving a client request, the thread goes back into the thread pool and gets ready to serve the next pending client’s request. Thread pooling will give better throughput, as less time is wasted in creating and destroying threads, because the application already has an idle pool of threads. The Fig. 7 (a) and (b) indicate clearly the purpose of this article is to cover a design that can be used to develop scalable data center without impacting performance.The last issue is parallel control. It is of practical significance to implement multiple master stations to receive data from all slave stations simultaneously and to control all slave stations in parallel. Each station can beuniquely identified with a physical address (ID number).Figure 6. The overall transfer time and overall response time But during the packet transmission, we can define that the all master stations deployed a unified virtual address to send and receive data. Once receiving a telemetering or teleindication packet whose destination address is the virtual address, the data center should forward the packet to all master stations. The virtual address plays as a multicast address. Similarly, for controlling all slave stations in parallel, we can define another virtual address.When the data center receives a telecontrol or teleadjusting packet with the defined address, it must multicast this packet to all slave stations. It is convenient and easy to carry out the parallel control though the data center.VI.CONCLUSION In this paper, a telecontrol system deployment scenario over the GPRS-Internet networks has been proposed and discussed in regard to real-time control, scalability, fault tolerance and parallel control. The primary objective of this paper is to present the design and implementation of the data center. In practice, it has been normally run for more than 7*24 hours. This work should be expanded to analyze from a security point of view. A key element of secure networking is the proper design and configuration of virtual private networks (VPNs) [5].R EFERENCES[1] GSM 03.60, “GPRS Service Description”, Stage 2, 1998.[2] Amitabh Mishra, “Performance and Architecture of SGSN andGGSN of General Packet Radio Service (GPRS)”, IEEE Press, pp.3494–3498 January 2001.[3] Christos Xenakis, Lazaros Merakos, “On Demand Network-wide VPNDeployment in GPRS”, IEEE Press, vol. 16, pp. 28–37, Nov.- Dev.2002.[4] Xiangguang Che, Hamalainen .S, Ryynanen.J, Moisio.M, “GPRSradio network performance simulation and optimization with dynamic simulator”, Proc. IEEE Symp. Communication Technology Proceedings (ICCT 2003), IEEE Press, pp. 935-939, doi: 10.1109/ICCT.2003.1209684.[5] B. Gleeson et al.,”A Framework for IP Based Virtual PrivateNetworks”, RFC 2764, Feb. 2000.Figure 7. The experiment results: (a) increase one master station (b) increase two slave stations中文译文：GPRS DTU 数据中心的详细实施及分析摘要:本文给出了一种基于GPRS远程控制系统体系结构的概述。

gprs模块数据采集原理
GPRS（GeneralPacketRadioService）是第二代数字移动电话技术（2G）的核心功能，也是无线网络的一项重要技术，它使无线网络的传输更加快速和稳定。

GPRS模块是一种具有GPRS功能的小型模块，用于从现场设备中采集数据，并通过GPRS无线传输技术将采集到的数据发送到中央服务器。

GPRS模块数据采集是目前用于网络监控系统的有效方法。

GPRS模块数据采集原理主要包括以下几个步骤：
1、采集：GPRS模块通过连接传感器、伺服器或计算机，采集设备中的实时数据。

2、处理：GPRS模块将采集到的数据进行处理，使之符合GPRS
传输的标准。

3、传输：GPRS模块将处理后的数据通过GPRS无线传输技术发送给中央服务器，以便进行远程监控。

4、响应：GPRS模块还可以响应中央服务器发送的远程命令，进行控制或管理现场设备。

GPRS模块数据采集的优点非常明显：它可以实现对环境的远程监控，远程管理和控制，可以减少与现场设备的维护成本，提高系统的可靠性和可用性，数据采集的速度也很快。

GPRS模块数据采集的安全性也是比较重要的一点，其安全性方面可以采取两种措施：一是采用加密机制，进行数据加密传输；二是采用身份验证功能，如使用密码、指纹等，以确保数据传输的安全性。

GPRS模块数据采集是一种非常有效的数据采集方式，具有安全性高、可靠性强的特点，目前已经在网络监控系统中广泛应用。

未来，它将被广泛应用于物联网领域，为物联网数据采集提供了更加有效、可靠、安全的采集方式。