DE10033302A1 - Method for mapping an SO interface on a remote connection - Google Patents

Abstract

Determining the cause of the malfunction in ISDN connections is very time-consuming, especially since it is only clear in the result whether the network termination or the terminal equipment are affected. The present invention makes it possible to transmit the data of an S¶0¶ interface to be measured to a central point in the network in order to be able to carry out monitoring there. The functions accept the connection, read out and form the data (C / I bits or D bits, or B¶1¶ or B¶2¶ bits) and initialization for transmission in the B channel are performed by one Executed module that is plugged into the C¶0¶ interface. The connection between the module and the central office in the ISDN network can be established by the module or after the destination number has been transmitted from the central office. The data is transmitted in such a way that the S¶0¶ interface to be measured is mapped in the central location. This enables cost-effective monitoring to determine the causes of faults.

Description

technical description

In the area of ISDN, customers repeatedly experience a malfunction. The Customers cannot check whether their problem is more on the ISDN connection or in the Terminal equipment is to be searched. As attentive to this from the fault acceptance is that the customer incurs costs if the error in the area of Uncertainty is exacerbated.

State of the art comments

There is currently no inexpensive way to set up an ISDN connection check the correct connection acceptance from a distance. Of course there is Measuring devices with which an ISDN basic connection can be checked. This However, measuring devices can only be used on site. The devices must also be set what certain ISDN knowledge requires, about which the customer usually does not dispose. If the customer instructs the fault acceptance to fail a service technician drives on site and performs an error rate measurement.

Task and technical solution

The invention is intended to give the customer an inexpensive way of being able to check his S ₀ interface for a correct connection establishment.

The object is achieved in accordance with claim 1 in such a way that the data of a connection establishment is transmitted from the customer's network termination (S ₀ interface) to a central point in the ISDN network and monitoring for the connection establishment can be carried out there.

The functions for transmitting the data are carried out by a module which the customer inserts into his network termination. An incoming connection is then established and from this moment on the C / I bits (layer 1 ) and then the D bits (layer 2 and layer 3 ) or B ₁ or B ₂ bits are transmitted to a central location.

The customer could get the module z. B. pick up at the T-Punkt or send by post to let.

The module works on an ISDN basic connection. Once connected with the service, data transmission 64 kbit / s, is set up by the network, the device takes the Connection and sends the D channel data or the in the corresponding B channel State of the C / I bits. In this way, monitoring is carried out from a central point carried out. This allows an error to be identified in the D channel.

The billing of the verification of an ISDN basic connection could be done via a Flat rate meter or a service number (e.g. 0180... Or 0190...).

Advantages and technical distinguishing features of the invention over the prior art of the technique

• - Less expensive way to get an ISDN basic connection to work properly to check out. The customer can connect inexpensively and independently check for any errors.
• - The customer receives a decision aid in which area the error lies. This enables him to avoid costs because he does not have to blindly hire a service to determine that the error is outside the area of responsibility of the service concerned.
  • 1. If the error is in the area of the connection, the service provider has saved the first use.

Description of the mode of operation of the invention (exemplary embodiment)

In Fig. 1 the device is shown as a block diagram.

The interface implementation (block 1 ) consists of a PEB 2080 , which converts the S ₀ interface to an IOM interface. Furthermore, the interface converter contains all functions necessary for access to the S ₀ interface (e.g. D-channel access).

Block 2 is an ISDN communications controller (ICC). The ICC is a PEB 2070 module, via which the entire communication control is handled and which sends the read data. It is controlled or configured by the micro controller (block 4 ). The microcontroller controls the establishment and termination of the connection via the ICC. Furthermore, the logic for reading out the data of the S ₀ interface to be measured (C / I bits or D bits, block 5 ) is controlled. The control and configuration by the microcontroller runs according to a predetermined program that is stored in a program memory (block 3 ). The program sequence is shown in FIG .

The program flow of establishing and closing a connection for the transmission of data to the central location comprises the following steps:
After starting the program routine, the ISDN communications controller is initialized to the parameters necessary for the transmission of data in the B channel. A loop now follows, in which a query for received messages (e.g. SETUP etc.) is continuously run in the receive buffer of the ICC. If such a message is received, it is temporarily stored in the microcontroller. Certain information, e.g. B. which channel was occupied (B1 or B2) or transmission sequence number and reception sequence number (I frame), saved in variables.

After this evaluation, the received message with the necessary response acknowledged. For this purpose, the individual bytes are written into the send buffer of the ICC and then broadcast. This happens at the time when the connection is activated. The readout logic is now activated by starting the interrupt control.

The flow chart for interrupt control is shown in FIG. 3.

The start of a new frame now causes an interrupt of the microcontroller. It now reads the fourth octet of the IOM data frame (D and C / I bits) of the S ₀ interface to be monitored via a parallel input. This happens for both the send and the receive direction. This data is cached in the microcontroller and compared with the data from the previous run. First the C / I bits of the transmitting side and then those of the receiving side are compared. If a change can be identified here, the changed data are brought into a specific format and sent to the central point via the B channel. However, if this is not the case, the D bits of the transmitting and receiving side are brought into a defined different format and sent via the B channel. The data format is selected so that one can distinguish between send data and receive data as well as C / I or D bits. The latter is achieved by inserting zero bits and positioning the 4 D bits in the octet of the B channel. During this time, the main program is in the query loop for new received messages and can therefore recognize a connection release request. If this is the case, the program then controls the disconnection of the data connection up to the end of the program.

In order to be able to select the module on the S ₀ interface, certain information must be transmitted to the central point beforehand (e.g. destination number, description of the fault). The module can also transmit the call number to the customer (at the measuring point).

The central point in the network to which the data of the S ₀ interface to be measured must be transferred must enable the data to be converted to the remote S ₀ interface in the opposite way, so that the S ₀ interface to be measured is in the central point is mapped.

In individual cases, the S ₀ interface to be measured can be identical to the S ₀ interface via which the module is selected.

Claims (2)

1. A method for mapping an S ₀ interface on a remote connection, characterized in that
that the data of the S ₀ interface to be measured are transmitted to a central point in the network,
that a connection is established between the S ₀ interface and the central point in the network,
that the data relate to C / I bits (layer 1 ) or D bits (layers 2 and 3 ) or B ₁ or B ₂ bits, after converting the S ₀ interface to be measured into an IOM interface be read out
that the data format for the transmission is selected in such a way that a distinction can be made between C / I bits and D bits and between the send and receive direction of the measurement data,
that the data is processed by a communications controller for transmission in the user channel,
that the modules for interface conversion, reading, forming and sending the data are incorporated in a module that must be connected to the interfaces,
that the module is used in the central point in the network in such a way that the interface conversion is undone, so that an image of the S ₀ interface to be measured is present, and
that the S ₀ interface shown in the central point in the network can be checked. 2. The method according to claim 1, characterized in that the connection between the module plugged into the S ₀ interface and the central point in the network is set up by the module itself or the central point in the network makes the selection after the module receives the destination number from the S ₀ interface has transmitted.