How To | Siemens TC65 specification

TC65 JAVA User's Guide	s
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8.11How To

This chapter is a step-by-step guide for using OTAP.

1.Do you need OTAP? Is there any chance that it might be necessary to update the Java application, install a new one or delete it? It could be that device is in the field and you cannot or do not want to update it over the serial line. If the answer is “yes” then read through the following steps, if the answer is “no” then consider simply setting the OTAP SMS password to protect your system. Then you are finished with OTAP.

2.Take a look at the parameters (chapter 8.3), which control OTAP. You need to decide which of them you want to allow to be changed over the air (by SMS) and which you do not. This is mainly a question of security and what can fit into a short message. Then set the “unchangeable” parameters with the AT command (at^sjotap).

3.Prepare the http server. The server must be accessible from your device over TCP/IP. That means there is a route from your device over the air interface to the http server and back. When in doubt, write a small Java application using the httpConnection Interface to test it.

4.Prepare the JAR and JAD files which are to be loaded over the air. Make sure that these files conform to the requirements listed in chapter 8.5 and that they represent a valid application which can be started by at^sjra.

5.Put the files (JAR and JAD) on the http Server. The files can either be publicly available or protected through basic authentication. When in doubt try to download the files from the server by using a common web browser on a PC, which can reach your http server over TCP/IP.

6.Prepare the SM sender. The sender must be able to send SMs, which conform to chapter 8.4, to your device. When in doubt try to send “normal” SMs to your device which can than be read out from the AT command interface.

7.Test with a local device. Send a suitable short message to your device, which completes the necessary parameter, sets and starts the operation. The operation is finished when the device reboots. You can now check the content of the file system and if the correct jar and jad files were loaded into the correct location.

8.Analyze errors. If the above test failed, looking at your device’s behavior and your http servers access log can give you a hint as to what went wrong:

•If the device did not terminate the running Java application and did not reboot, not even after the safety timeout, either your SM was not understood (probably in the wrong format) or it did not properly authenticate (probably used the wrong password) or your parameter set is incomplete for the requested operation.

•If the device terminated the running Java application, but did not access your http server, and rebooted after the safety timeout, there were most likely some problems when opening the network connection. Check your network parameters.

•If the device downloaded the jad and possibly even the jar file but then rebooted without saving them in the file system, most likely one of the errors outlined in chapter 8.5 occurred. These are also the only errors which will return a response. They are posted to the http server if the jad file contains the required URL.

9.Start update of remote devices. If you were able to successfully update your local device, which is hopefully a mirror of all your remote devices, you can start the update of all other devices.

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26.09.2005

TC65 specifications

The Siemens TC65 is a compact and powerful GSM/GPRS module designed for a wide range of mobile communication applications. With its robust features, the TC65 perfectly meets the growing demands for connectivity in various industries, including automotive, telematics, and industrial automation.

A standout feature of the TC65 is its compact size, allowing it to be easily integrated into various devices without compromising on performance. The module supports GSM (Global System for Mobile Communications) and GPRS (General Packet Radio Service), providing reliable and efficient voice and data transmission.

One of the key technologies incorporated in the TC65 is its integrated TCP/IP stack, which allows for seamless internet connectivity and enables application developers to create IoT solutions with ease. This capability is essential for remote monitoring, data logging, and other applications that require continuous data exchange.

The TC65 also boasts extensive multimedia capabilities, including support for SMS, MMS, and voice calls. This makes it suitable for applications that require not only data transmission but also communication features. Additionally, it supports various codecs for voice compression, ensuring high-quality audio in voice applications.

Enhanced security features are another highlight of the TC65. It incorporates comprehensive security protocols to safeguard data transmission, making it suitable for sensitive applications in finance, healthcare, and other critical sectors. The module also includes an integrated SIM application toolbox that supports the development of secure and customizable applications.

For developers, the TC65 offers an easy-to-use software development kit (SDK), simplifying the process of application development. This means that businesses can quickly create and deploy solutions tailored to their specific needs.

The module operates across a wide voltage range and is designed to tolerate challenging environmental conditions, making it ideal for industrial use. It supports various interfaces, including UART, GPIO, and I2C, enabling it to connect with a variety of peripherals and sensors, thus expanding its usability.

In summary, the Siemens TC65 combines compact design, versatile communication capabilities, advanced security features, and developer-friendly resources, making it an excellent choice for anyone looking to implement reliable and sophisticated GSM/GPRS communication in their applications. The TC65 is a valuable asset in the evolving landscape of connected devices and IoT solutions.