KR101010813B1 - Multi tracer for mobile communication device - Google Patents

Abstract

The present invention relates to an error tracking device that supports multiple operations during operation outputted for debugging purposes in a GSM terminal. When testing defects that are rarely reproducible, traces of several samples are simultaneously detected in one PC. The present invention relates to an error tracking device of a mobile communication terminal, which is capable of performing error tracking for debugging by connecting a plurality of terminals to a single PC, each of which has a number of terminals to be tracked. An input RS-232C interface unit for interfacing, a first processor for converting data of each terminal input through the input RS-232C interface unit into a single TDM signal, and receiving the converted time division multiplex (TDM) signal A second processor for converting into an RS-232C signal and converting one serial data through the second processor; This can be achieved by including an output RS-232C interface unit for transmitting the signal to the PC side.

Description

Error tracking device of mobile communication terminal {MULTI TRACER FOR MOBILE COMMUNICATION DEVICE}

1 is an exemplary view showing the configuration of an error tracking device of a conventional mobile communication terminal.

Figure 2 is an exemplary view showing a serial communication protocol used in the conventional error tracking device.

3 is an exemplary view showing the configuration of an error tracking device of a mobile communication terminal according to the present invention.

4 is an internal serial interface configuration diagram of a processor (MPC860) applied to the present invention.

5 is a block diagram showing a detailed configuration of a multiple tracker according to the present invention.

6 is an exemplary view showing a serial communication protocol used in the error tracking device according to the present invention.

* Description of the symbols for the main parts of the drawings *

51 ~ 54: Input RS-232C interface 55: Output RS-232C interface

56: first processor 57: second processor

58,59 code memory

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an error tracking device of a mobile communication terminal, and more particularly, to an error tracking device supporting multiple errors during operation outputted for debugging purposes in a GSM terminal. The present invention relates to an error tracking device of a mobile communication terminal that enables a single PC to simultaneously detect traces of large samples.

In general, it is conventionally configured to track an error during operation by connecting one mobile communication terminal to one PC. Of course, a PC having two serial ports can connect up to two terminals, but in most cases, it is structured to connect one terminal to a PC.

1 is an exemplary view showing the configuration of an error tracking device of a conventional mobile communication terminal. As a GSM terminal 11 for tracking an error during an actual operation, trace data is transmitted through a cable 12 in a serial format. do.

Here, the cable 12 is a parallel interface, and serial data from the terminal is also transmitted through this interface.

The data transmitted through the cable 12 is converted into RS-232C format of serial data received from the terminal 11 through a format conversion jig 13 and transmitted. Here, the format conversion jig 13 multiplexes the power control and serial data of the terminal.                         

Next, the trace data converted into RS-232C format through the format conversion jig 13 is transmitted to the serial port of the PC 15 through the RS-232C cable 14.

FIG. 2 is an exemplary diagram illustrating a serial communication protocol used in a conventional error tracking apparatus. Referring to the exemplary diagrams of FIGS. 1 and 2, the operation of the conventional apparatus will be described below.

First, the trace data generated inside the terminal is composed of a format as shown in FIG. 2 and is level-shifted to conform to the RS-232C transmission standard through the format conversion jig 13 and transmitted to the PC through the cable 14. do.

The data transmitted as described above is separated into respective IDs by an application program (error tracking program) inside the PC to show the contents desired by the user. In this case, the application program determines whether the data is transmitted by determining the presence or absence of the STX in FIG. 2, and if so, examines the following header to determine what data is present.

In general, the error tracking system has IDs such as L1, MMI, Riviera, and Test Mode. By sprinkling the data with the same ID in the same window, the user can check what part of the terminal is currently being performed. Based on this, the cause of the defect can be found and corrected.

However, the error tracking technique described above should be reproduced with a large number of samples for a rarely reproducible defect. In the conventional technique, only one sample can be traced in one PC, so a large number of samples can be reproduced. There is a problem that can not be judged, and moreover, if a large number of samples are installed, it is difficult to decorate such a test environment because the amount of PC is required.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and relates to an error tracking device which supports multiple operations (Trace) outputted for debugging purposes in a GSM terminal. It is an object of the present invention to provide an error tracking device of a mobile communication terminal that enables a PC to detect traces of several samples at the same time.

In order to accomplish the above object, the present invention provides an apparatus for connecting a plurality of terminals to a single PC to perform error tracking for debugging, wherein the input RS interfaces each of a plurality of terminals to track errors. A first processor for converting data of each terminal input through the input RS-232C interface into a single TDM signal, and receiving the converted time division multiplex (TDM) signal; And an output RS-232C interface unit which transmits a signal converted into one serial data through the second processor to the PC side.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is an example of the configuration of an error tracking device of a mobile communication terminal according to the present invention. In the conventional case, only one terminal is connected to one PC to track an error during operation. You can connect to one PC to track errors during operation.

Referring to FIG. 3, a plurality of terminals 31 for tracking errors during operation, a cable 32 connecting each terminal to each format conversion jig 33, and each format conversion jig 33 RS-232C cable (34) for connecting the data converted into the RS-232C format to the multiple tracker 35 of the present invention, and receiving the trace data output from each terminal through the RS-232C cable to each terminal It is configured to include a multi-tracker 35 to give the ID, and to convert each data into a single serial data and output to the PC (37).

Here, the multi-tracker 35 receives serial data of all GSM terminals connected through each format conversion jig 33, assigns IDs to each terminals, adds the IDs to serial data, and receives them from four terminals. It is a device for making serial data into one serial data and transmitting the data. In this case, since the output data format is also RS-232C format, the cable 36 for connecting the multiple tracker 35 and the PC is also an RS-232C cable.

The PC 37 is equipped with an application program (error tracking program) as in the prior art to process trace data received from each terminal.

The multiple tracker 35 of the present invention uses a time division multiplex (TDM) concept, and for this purpose, a processor of a power PC series (MPC860) that can use a time slot assigner (TSA) inside the multiple tracker. As the main controller unit (MCU).

For reference, an operating characteristic of the processor MPC860 used in the present invention will be described with reference to the internal serial interface configuration shown in FIG. 4.

As shown in FIG. 4, the processor MPC860 has six serial ports, and includes SI RAM 41, which has routing information, which can be allocated to each time slot, and stores Rx / Tx information. It includes a control unit 42 for loading it to the TSA or sending it to the U-Bus according to the control signal, and registers 43 to 46 for setting the TDM information.

The information allocated to the RAM through the U-Bus is allocated a time slot through the TSA 47, and the Rx information is referred to as each serial interface RAM through the multiplexer (MUX, 48). It is a kind of communication buffer and has pointer information about RAM.), And Tx information is transmitted as TDM signal through TDM pin.

As described above, the serial interface of the processor MPC860 to be applied to the present invention has been outlined. Further details thereof will obscure the gist of the present invention, and thus description thereof will be omitted.

FIG. 5 is a block diagram showing a detailed configuration of a multiple tracker according to the present invention, and includes an input RS-232C interface unit 51 to 54 for interfacing a plurality of terminals to be tracked, respectively, and the input RS-232C interface unit. An output RS-232C interface unit 55 for making each received data into one serial data for transmission to the PC side, and a first processor 56 which transforms the data input through the input RS-232C interface unit into a TDM signal; And a second processor 57 which receives the serialized signal by the TDM method and converts the RS-232C signal into an RS-232C signal.

In this case, the code memory units 58 and 59, which are omitted from the configuration description, are memories in which programs necessary for the operations of the first and second processors are stored.

Hereinafter, the operation and operation of the device configured as described above are as follows.

First, the input / output RS-232C interface unit 51 to 55 convert the trace data transmitted from the interfaced terminal to the RS-232C format and convert the data into one serial data and output the data to the PC side. It is a port.

The serial data received through the input RS-232C interface unit 51 is sent to the first processor 56. The first processor 56 is the above-described MPC860 processor, and each serial terminal of the terminal is an interface of SCC1 to SCC4. It takes the data and converts it into a TDM signal.

In order to support the multiple interfaces as described above, each terminal should set the baud rate at a speed of 19200 bps, because the signal transmitted to the PC through the output RS-232C interface unit 55, four terminals Since the signal from the serialized signal is sent out, it should be transmitted at a speed of at least four times. Since the maximum baud rate supported by the processor (MPC860) is 115200bps, it is slower than 1/4 of this standard RS-232C. This is because the baud rate is 19200bps.                     

As described above, the serial data inputted to each SCC interface knows which port is transmitted on the first header as shown in FIG. 6 before being switched to the 1 TDM scheme supporting a total of 32 channels. A header (Port ID) is added that enables it. The serialized signal in this way is transmitted to the second processor 57 via the TDMa pin.

Then, the second processor converts the signal transmitted from the first processor to the RS-232C signal through the TDMa Pin, and allocates SCC1 to the PC side COM port at a baud rate of 115200bps.

6 is an exemplary diagram showing a serial communication protocol used in the error tracking apparatus according to the present invention. Compared with the conventional protocol shown in FIG. 2, one conventional protocol is changed to four protocols in which each port is serialized. And, by adding a port ID (Port ID) at the beginning before each protocol starts, it is possible to express the traces of each terminal differently by distinguishing them from the application program mounted on the PC.

As described above, the error tracking device of the mobile communication terminal of the present invention supports multiple errors during operation outputted for debugging purposes in the GSM terminal, so that errors during operation of many samples can be tracked, and one PC This allows you to debug multiple terminals, improving time savings and convenience.

Claims (4)

In the device to connect a number of terminals to a single PC to perform error tracking for debugging, An input RS-232C interface unit for respectively interfacing a plurality of terminals to be tracked for errors; A first processor converting data of each terminal input through the input RS-232C interface into a single TDM signal; A second processor configured to receive the converted time division multiplex (TDM) signal and convert the received TDM signal into an RS-232C signal; And an output RS-232C interface unit for transmitting a signal converted into one serial data to the PC side through the second processor. The error tracking device of claim 1, wherein each terminal that interfaces with the error tracking device sets a baud rate at a speed of 19200 bps. The method of claim 1, wherein the serial data input to the error tracking device further inserts a port ID in the first header before each protocol starts so as to know through which port the data is transmitted. Error tracking device of a mobile communication terminal, characterized in that configuration. 2. The error tracking device of claim 1, wherein the communication speed output to the PC side through the output RS-232C port of the second processor is set at a baud rate of 115200 bps.

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